A method of transplanting a desired emotional state from a donor to a recipient, comprising determining an emotional state of the donor; recording neural correlates of the emotional state of the donor who is in the desired emotional state; analyzing neural correlates of the emotional state of the donor to decode at least one of a temporal and a spatial pattern corresponding to the desirable emotional state; converting said at least one of a temporal and a spatial pattern corresponding to the desirable emotional state into a neurostimulation pattern; storing the neurostimulation pattern in the nonvolatile memory; retrieving the neurostimulation pattern from the nonvolatile memory; stimulating the recipients brain with at least one stimulus modulated with the neurostimulation pattern to induce the desired emotional state in the recipient.

Patent
   11318277
Priority
Dec 31 2017
Filed
Dec 31 2018
Issued
May 03 2022
Expiry
Jun 07 2039
Extension
158 days
Assg.orig
Entity
Small
1
6818
currently ok
1. A method of recording neural correlates of a desired emotional state from a donor, comprising:
determining an emotional state of the donor;
recording neural correlates of the desired emotional state of the donor when the donor is in the desired emotional state;
analyzing the neural correlates of the desired emotional state of the donor to decode at least a temporal pattern corresponding to the desired emotional state;
converting said at least the temporal pattern corresponding to the desired emotional state into a dynamically-modulated neurostimulation pattern correlated with the temporal pattern;
storing the dynamically-modulated neurostimulation pattern in a nonvolatile memory,
retrieving the dynamically-modulated neurostimulation pattern from the nonvolatile memory; and
stimulating a recipient's brain with at least one stimulus modulated with the dynamically-modulated neurostimulation pattern to induce the desired emotional state in the recipient.
13. A system for recording neural correlates of a desired emotional state from a donor, comprising:
a first input configured to receive information reflecting a determined emotional state of the donor;
a second input configured to receive an informational representation of the neural correlates of the determined emotional state of the donor when the donor is in a predetermined desired emotional state;
at least one processor configured to:
analyze the neural correlates of the predetermined desired emotional state of the donor to decode at least a temporal pattern corresponding to the predetermined desired emotional state;
convert at least the temporal pattern corresponding to the desired emotional state into a temporally-modulated neurostimulation pattern correlated with the at least temporal pattern;
store the temporally-modulated neurostimulation pattern in a non-volatile memory;
retrieve the temporally-modulated neurostimulation pattern from the nonvolatile memory; and
stimulate a recipient's brain with at least one stimulus modulated with the temporally-modulated neurostimulation pattern to induce the desired emotional state in the recipient; and
the non-volatile memory configured to store the temporally-modulated neurostimulation pattern.
18. A system for recording neural correlates of different emotional states from a plurality of donors, comprising:
a relational database of neural correlates of emotional states, stored in a non-transitory computer readable medium, the relational database comprising a first table storing a plurality of respective different emotional states, linked with a second table storing neural correlate information associated with respective different emotional states;
the first table comprising records of a temporal pattern corresponding to each of the plurality of respective different emotional states, decoded from recorded neural correlates of each respective emotional state from each of the plurality of donors, in association with a determined emotional state of the respective donor while the respective donor is in the plurality of respective different emotional states; and
the second table comprising records linked to records of the first table storing information associated with the plurality of respective different emotional states, selectively correlated with at least the temporal pattern corresponding to each respective different emotional state,
the relational database being accessible by receipt of an identification of a respective emotional state and responsive by providing information from the second table linked to the respective emotional state; and
a stimulator configured to stimulate a recipient's brain with at least one stimulus modulated with a dynamically-modulated neurostimulation pattern dependent on the temporal pattern corresponding to the identification of the respective emotional state, to induce a desired emotional state in the recipient.
2. The method of claim 1, wherein the neural correlates are brainwaves of the donor.
3. The method of claim 2, wherein the step of analyzing neural correlates comprises identifying principal components of the brainwaves.
4. The method of claim 3, wherein the identifying principal components comprises performing one of a principal component analysis (PCA), a curvilinear principal component analysis, an independent component analysis (ICA), a Karhunen-Loève transform (KLT), a singular value decomposition (SVD), and a Factor analysis.
5. The method of claim 3, wherein the step of analyzing neural correlates comprises performing a frequency domain analysis.
6. The method of claim 5, wherein the step of performing the frequency analysis comprises performing one of a Fourier Transform, a Laplace Transform, a Fourier-Stieltjes transform, a Gelfand transform, time-frequency analysis, a short-time Fourier transform, and a fractional Fourier transform.
7. The method of claim 1, wherein the desired emotional state is one of happiness, joy, gladness, cheerfulness, bliss, delight, ecstasy, optimism, exuberance, merriment, joviality, vivaciousness, pleasure, excitement, sexual arousal, relaxation, harmony, and peace.
8. The method of claim 1, wherein said at least one stimulus is one of a dynamically modulated current, a dynamically modulated magnetic field, a dynamically modulated optical stimulus, a dynamically modulated sonic signal, a dynamically modulated tactile signal and a dynamically modulated olfactory signal.
9. The method of claim 1, wherein the recipient is the donor at a point in time subsequent to the time of recording the neural correlates of the emotional state of the donor.
10. The method of claim 1, further comprising:
developing a brain model of the recipient; and
adjusting said at least one stimulus in accordance with the model to adjust for the differences between the recipient's brain and the donor's brain.
11. The method of claim 1, further comprising the step of administering a pharmacological agent to the recipient to facilitate response of the recipient to said at least one stimulus to induce the desired emotional state.
12. The method of claim 1, further comprising performing, by the recipient, a physical exercise in conjunction with the at least one stimulus.
14. The system of claim 13, wherein the neural correlates are brainwaves of the donor.
15. The system of claim 13, wherein the temporally-modulated neurostimulation pattern is one of a temporally-modulated electrical and a magnetic brain stimulation pattern.
16. The system of claim 13, wherein the temporally-modulated neurostimulation pattern is one of a temporally-modulated audio and visual stimulation pattern.
17. The system of claim 13, wherein the at least one processor comprises at least one single-instruction multiple-data processor.
19. The system of claim 18, wherein the neural correlates of each respective different emotional state are brainwaves.
20. The system of claim 18, wherein the recording of neural correlates comprises performing at least one of an electroencephalogram and a magnetoencephalogram.

The present application is a non-provisional of, and claims benefit of priority from, U.S. Provisional Patent Applications No. 62/612,565, filed Dec. 31, 2017, and No. 62/660,839 filed on Apr. 20, 2018, both of which are expressly incorporated herein by reference in their entirety.

The present invention generally relates to the fields of neuroenhancement, neuromodulation, neurostimulation, and brain entrainment, and, more specifically, to devices, systems, and methods for selectively inducing brainwave activity patterns in humans or animals that correspond to, or enhance, an emotion or emotional response.

People often substitute an authentic experience by a replica thereof. Those who cannot visit the Louvre Museum, can look at the Mona Lisa on a reproduction. Anybody who has seen the real Mona Lisa in the Louvre can testify that the emotional experience is completely different from just looking at a reproduction. Yet people often substitute reproductions for authentic works of art, when the latter are not readily accessible. The emotional response to viewing a reproduction pales in comparison to the emotional response to viewing an authentic piece of art in a museum. Looking at a photograph of the Grand Canyon is incomparable with experiencing the real thing—visiting the Grand Canyon, which is a breathtaking experience. Yet, people unable to travel, often replace the authentic experience of traveling and visiting new places with watching videos on the Travel Channel or on the Internet. Needless to say, watching TV or a video on the Internet is a poor substitute for the real experience of traveling and does not elicit the strong emotions, a person experiences when visiting new places.

Because of lack of excitement in their daily lives people seek excitement in the movies. Movies tend to be more immersive experiences and can produce strong emotional responses. Many movie-goers cry while watching movies. A sentimental, emotionally-charged movie is referred to as a tear-jerker due to its ability to elicit a strong emotional response, resulting in tears. However, the emotions experience of watching a movie cannot be compared with the broad range of emotions experienced in real life.

Recent advancements in 3D viewing technology and the emergence of Virtual Reality (VR) devices produce more realistic representation of reality they depict. However, even VR devices are incapable of producing emotional responses comparable to the emotions experienced in real life.

A viewer may benefit from enhanced emotional responses associated with viewing art reproductions, watching TV, movies, Internet videos, or Virtual Reality.

Some people lack certain emotions. For example, sociopathic personalities are incapable of experiencing emotions of empathy and compassion. A number of neurologic, psychiatric and psychological pathologies may affect the ability to experience certain emotions. Patients suffering from advanced stages of Parkinson and Alzheimer's diseases often exhibit subdued emotional response. Patients affected by paranoid schizophrenia, brain injury, or dementia sometimes experience Capgras delusion. They see a familiar face of a spouse or another family member but do not experience emotional response they expect to experience when seeing a face of a close family member, which leads them to believe that they live with an imposter that only “looks like” their family member; they complain about a doppelganger living with them. It may be beneficial to artificially enhance the emotional response of a patient, bringing it to the normal level expected of a healthy person.

It is well known that memory retention is affected by the emotional state of the person. Emotionally-charged experiences are etched in the memory, whereas experiences not associated with high emotions are easily forgotten. Artificially raising emotional levels during study may significantly increase the retention of the information and ease its subsequent recall.

It has been observed in neuroscience that various emotions correlate with different frequency and location of the brainwaves. Accordingly, inducing in a subject the brainwaves of particular frequency in a particular location may induce and/or enhance the desired emotional response.

Emotions are viewed as discrete and dimensional. The discrete framework classifies emotional states as physiological and behavioral manifestations of discrete emotions such as anger, happiness, etc. The dimensional perspective organizes emotional states by two factors, valence (positive/negative) and arousal (calm/exciting).

Emotions are thought to be associated with different parts of the brain:

Frontal Lobe (movement of the body; personality; concentration, planning, problem solving; meaning of words; emotional reactions; speech; smell); Parietal Lobe (touch and pressure; taste; body awareness); Temporal Lobe (hearing; recognizing faces; emotion; long-term memory); Occipital Lobe (sight); Cerebellum (Latin for little brain, fine motor (muscle) control; balance and coordination (avoid objects and keep from falling)); Limbic Lobe (controls emotions like happiness, sadness, and love).

Each reference and document cited herein is expressly incorporated herein by reference in its entirety, for all purposes.

Time in a biological matter Almost everything in biology is subject to change over time. These changes occur on many different time scales, which vary greatly. For example, there are evolutionary changes that affect entire populations overtime rather than a single organism. Evolutionary changes are often slower than a human time scale that spans many years (usually, a human lifetime). Faster variations of the timing and duration of biological activity in living organisms occur, for example, in many essential biological processes in everyday life: in humans and animals, these variations occur, for example, in eating, sleeping, mating, hibernating, migration, cellular regeneration, etc. Other fast changes may include the transmission of a neural signal, for example, through a synapse, such as the Calyx of Held, a particularly large synapse in the auditory central nervous system of mammals that can reach transmission frequencies of up to 50 Hz. With recruitment modulation, the effective frequencies can be higher. A single nerve impulse can reach a speed as high as one hundred meters (0.06 mile) per second (Kraus, David. Concepts in Modern Biology. New York: Globe Book Company, 1969: 170.). Myelination of axons can increase the speed of transmission by segmenting the membrane depolarization process.

Many of these changes overtime are repetitive a rhythmic and are described as some frequency or oscillation. The field of chronobiology, examines such periodic (cyclic) phenomena in living organisms and their adaptation, for example, to solar and lunar-related rhythms (DeCoursey, et al. (2003).) These cycles are also known as biological rhythms. The related terms “chronomics” and “chronome” have been used in some cases to describe either the molecular mechanisms involved in chronobiological phenomena or the more quantitative aspects of chronobiology, particularly where comparison of cycles between organisms is required. Chronobiological studies include, but are not limited to, comparative anatomy, physiology, genetics, molecular biology and behavior of organisms within biological rhythms' mechanics (DeCoursey et al. (2003).). Other aspects include epigenetics, development, reproduction, ecology, and evolution.

The most important rhythms in chronobiology are the circadian rhythms, roughly 24-hour cycles shown by physiological processes in all organisms. They are regulated by circadian clocks. The circadian rhythms can be further broken down into routine cycles during the 24-hour day (Nelson R J. 2005. An Introduction to Behavioral Endocrinology. Sinauer Associates, Inc.: Massachusetts. Pg. 587.) All animals can be classified according to their activity cycles: Diurnal, which describes organisms active during daytime; Nocturnal, which describes organisms active in the night, and Crepuscular, which describes animals primarily active during the dawn and dusk hours (e.g., white-tailed deer, some bats).

While circadian rhythms are defined as regulated by endogenous processes, other biological cycles may be regulated by exogenous signals. In some cases, multi-trophic systems may exhibit rhythms driven by the circadian dock of one of the members (which may also be influenced or reset by external factors).

Many other important cycles are also studied, including: Infradian rhythms, which are cycles longer than a day. Examples include circannual or annual cycles that govern migration or reproduction cycles in many plants and animals, or the human menstrual cycle; ultradian rhythms, which are cycles shorter than 24 hours, such as the 90-minute REM cycle, the 4-hour nasal cycle, or the 3-hour cycle of growth hormone production; tidal rhythms, commonly observed in marine life, which follow the roughly 124-hour transition from high to low tide and back; lunar rhythms, which follow the lunar month (29.5 days). They are relevant for example, to marine life, as the level of the tides is modulated across the lunar cycle; and gene oscillations—some genes are expressed more during certain hours of the day than during other hours.

Within each cycle, the time period during which the process is more active is called the acrophase (Refinetti, Roberto (2006). Circadian Physiology. CRC Press/Taylor & Francis Group. ISBN 0-8493-2233-2. Lay summary). When the process is less active, the cycle is in its bathyphase, or trough phase. The particular moment of highest activity is the peak or maximum; the lowest point is the nadir. How high (or low) the process gets is measured by the amplitude.

Neural Correlates A neural correlate of an emotional or mental state is an electro-neuro-biological state or the state assumed by some biophysical subsystem of the brain, whose presence necessarily and regularly correlates with such specific emotional or mental states. All properties credited to the mind, including consciousness, emotion, and desires are thought to have direct neural correlates. For our purposes, neural correlates of an emotional or mental state can be defined as the minimal set of neuronal oscillations that correspond to the given emotional or mental state. Neuroscience uses empirical approaches to discover neural correlates of emotional or mental state.

Mental State A mental state is a state of mind that a subject is in. Some mental states are pure and unambiguous, while humans are capable of complex states that are a combination of mental representations, which may have in their pure state contradictory characteristics. There are several paradigmatic states of mind that a subject has: love, hate, pleasure, fear, and pain. Mental states can also include a waking state, a sleeping state, a flow (or being in the “zone”), a will (desire) for something, and a mood (a mental state). A mental state is a hypothetical state that corresponds to thinking and feeling, and consists of a conglomeration of mental representations. A mental state is related to an emotion, though it can also relate to cognitive processes. Because the mental state itself is complex and potentially possesses inconsistent attributes, clear interpretation of mental state through external analysis (other than self-reporting) is difficult or impossible. However, some studies report that certain attributes of mental state or thought processes may, in fact, be determined through passive monitoring, such as EEG, or fMRI with some degree of statistical reliability. In most studies, the characterization of mental state was an endpoint, and the raw signals, after statistical classification or semantic labeling, are superseded. The remaining signal energy treated as noise.

A number of studies report that certain attributes of mental state or thought processes may in fact be determined through passive monitoring, such as EEG, with some degree of statistical reliability. In most studies, the characterization of mental state was an endpoint, and the raw signals, after statistically classification or semantic labelling, are superseded and the remaining signal energy treated as noise.

Brain The brain is a key part of the central nervous system, enclosed in the skull. In humans, and mammals more generally, the brain controls both autonomic processes, as well as cognitive processes. The brain (and to a lesser extent the spinal cord) controls all volitional functions of the body and interprets information from the outside world. Intelligence, memory, emotions, speech, thoughts, movements and creativity are controlled by the brain. The central nervous system also controls autonomic functions and many homeostatic and reflex actions, such as breathing, heart rate, etc. The human brain consists of the cerebrum, cerebellum, and brainstem. The brainstem includes the midbrain, the pons, and the medulla oblongata. Sometimes the diencephalon, the caudal part of the forebrain, is included.

The brain is composed of neurons, neuroglia (a.k.a., glia), and other cell types in connected networks that integrate sensory inputs, control movements, facilitate learning and memory, activate and express emotions, and control all other behavioral and cognitive functions. Neurons communicate primarily through electrochemical pulses that transmit signals between connected cells within and between brain areas. Thus, the desire to noninvasively capture and replicate neural activity associated with cognitive states has been a subject of interest to behavioral and cognitive neuroscientists.

Technological advances now allow for non-invasive recording of large quarries of information from the brain at multiple spatial and temporal scales. Examples include electroencephalogram (“EEG”) data using multi-channel electrode arrays placed on the scalp or inside the brain, magnetoencephalography (“MEG”), magnetic resonance imaging (“MRI”), functional data using functional magnetic resonance imaging (“fMRI”), positron emission tomography (“PET”), near-infrared spectroscopy (“NIRS”), single-photon emission computed tomography (“SPECT”), and others.

Noninvasive neuromodulation technologies have also been developed that can modulate the pattern of neural activity, and thereby cause altered behavior, cognitive states, perception, and motor output. Integration of noninvasive measurement and neuromodulation techniques for identifying and transplanting brain states from neural activity would be very valuable for clinical therapies, such as brain stimulation and related technologies often attempting to treat disorders of cognition.

The brainstem provides the main motor and sensory innervation to the face and neck via the cranial nerves. Of the twelve pairs of cranial nerves, ten pairs come from the brainstem. This is an extremely important part of the brain, as the nerve connections of the motor and sensory systems from the main part of the brain to the rest of the body pass through the brainstem. This includes the corticospinal tract (motor), the posterior column-medial lemniscus pathway (fine touch, vibration sensation, and proprioception), and the spinothalamic tract (pain, temperature, itch, and crude touch). The brainstem also plays an important role in the regulation of cardiac and respiratory function. It also regulates the central nervous system and is pivotal in maintaining consciousness and regulating the sleep cycle. The brainstem has many basic functions including controlling heart rate, breathing, sleeping, and eating.

The function of the skull is to protect delicate brain tissue from injury. The skull consists of eight fused bones: the frontal, two parietal, two temporal, sphenoid, occipital and ethmoid. The face is formed by 14 paired bones including the maxilla, zygoma, nasal, palatine, lacrimal, interior nasal conchae, mandible, and vomer. The bony skull is separated from the brain by the dura, a membranous organ, which in turn contains cerebrospinal fluid. The cortical surface of the brain typically is not subject to localized pressure from the skull. The skull, therefore, imposes a barrier to electrical access to the brain functions, and in a healthy human, breaching the dura to access the brain is highly disfavored. The result is that electrical readings of brain activity are filtered by the dura, the cerebrospinal fluid, the skull, the scalp, hair, resulting in a loss of potential spatial resolution and amplitude of signals emanating from the brain. While magnetic fields resulting from brain electrical activity are accessible, the spatial resolution using feasible sensors is also limited.

The cerebrum is the largest part of the brain and is composed of right and left hemispheres. It performs higher functions, such as interpreting inputs from the senses, as well as speech, reasoning, emotions, learning, and fine control of movement. The surface of the cerebrum has a folded appearance called the cortex. The human cortex contains about 70% of the nerve cells (neurons) and gives an appearance of gray color (grey matter). Beneath the cortex are long connecting fibers between neurons, called axons, which make up the white matter.

The cerebellum is located behind the cerebrum and brainstem. It coordinates muscle movements, helps to maintain balance and posture. The cerebellum may also be involved in some cognitive functions such as attention and language, as well as in regulating fear and pleasure responses. There is considerable evidence that the cerebellum plays an essential role in some types of motor learning. The tasks where the cerebellum most clearly comes into play are those in which it is necessary to make fine adjustments to the way an action is performed. There is a dispute about whether learning takes place within the cerebellum itself, or whether it merely serves to provide signals that promote learning in other brain structures. Cerebellum also plays an important role in sleep and long-term memory formation.

The brain communicates with the body through the spinal cord and twelve pairs of cranial nerves. Ten of the twelve pairs of cranial nerves that control hearing, eye movement, facial sensations, taste, swallowing and movement of the face, neck, shoulder and tongue muscles originate in the brainstem. The cranial nerves for smell and vision originate in the cerebrum.

The right and left hemispheres of the brain are joined by a structure consisting of fibers called the corpus callosum. Each hemisphere controls the opposite side of the body. The right eye sends visual signals to the left hemisphere and vice versa. However, the right ear sends signals to the right hemisphere, and the left ear sends signals to the left hemisphere. Not all functions of the hemispheres are shared. For example, speech is processed exclusively in the left hemisphere.

The cerebral hemispheres have distinct structures, which divide the brain into lobes. Each hemisphere has four lobes: frontal, temporal, parietal, and occipital. There are very complex relationships between the lobes of the brain and between the right and left hemispheres:

Frontal lobes control judgment, planning, problem-solving, behavior, emotions, personality, speech, self-awareness, concentration, intelligence, body movements.

Temporal lobes control understanding of language, memory, organization, and hearing.

Parietal lobes control the interpretation of language; input from vision, hearing, sensory, and motor, temperature, pain, tactile signals, memory, spatial and visual perception.

Occipital lobes interpret visual input (movement, light, color).

A neuron is a fundamental unit of the nervous system, which comprises the autonomic nervous system and the central nervous system.

Brain structures and particular areas within brain structures include but are not limited to hindbrain structures (e.g., myelencephalon structures (e.g., medulla oblongata, medullary pyramids, olivary body, inferior olivary nucleus, respiratory center, cuneate nucleus, gracile nucleus, intercalated nucleus, medullary cranial nerve nuclei, inferior salivatory nucleus, nucleus ambiguous, dorsal nucleus of the vagus nerve, hypoglossal nucleus, solitary nucleus, etc.), metencephalon structures (e.g., pons, pontine cranial nerve nuclei, chief a pontine nucleus of the trigeminal nerve sensory nucleus (V), motor nucleus for the trigeminal nerve (V), abducens nucleus (VI), facial nerve nucleus (VII), vestibulocochlear nuclei (vestibular nuclei and cochlear nuclei) (VIII), superior salivatory nucleus, pontine tegmentum, respiratory centers, pneumotaxic center, apneustic center, pontine micturition center (Barrington's nucleus), locus coeruleus, pedunculopontine nucleus, laterodorsal tegmental nucleus, tegmental pontine reticular nucleus, superior olivary complex, paramedian pontine reticular formation, cerebellar peduncles, superior cerebellar peduncle, middle cerebellar peduncle, interior cerebellar peduncle, fourth ventricle, cerebellum, cerebellar vermis, cerebellar hemispheres, anterior lobe, posterior lobe, flocculonodular lobe, cerebellar nuclei, fastigial nucleus, interposed nucleus, globose nucleus, emboliform nucleus, dentate nucleus, etc.)), midbrain structures (e.g., tectum, corpora quadrigemina, inferior colliculi, superior colliculi, pretectum, tegmentum, periaqueductal gray, parabrachial area, medial parabrachial nucleus, lateral parabrachial nucleus, subparabrachial nucleus (Kolliker-Fuse nucleus), rostral interstitial nucleus of medial longitudinal fasciculus, midbrain reticular formation, dorsal raphe nucleus, red nucleus, ventral tegmental area, substantia nigra, pars compacta, pars reticulata, interpeduncular nucleus, cerebral peduncle, cms cerebri, mesencephalic cranial nerve nuclei, oculomotor nucleus (III), trochlear nucleus (IV), mesencephalic duct (cerebral aqueduct, aqueduct of sylvius), etc.), forebrain structures (e.g., diencephalon, epithalamus structures (e.g., pineal body, habenular nuclei, stria medullares, taenia thalami, etc.), third ventricle, thalamus structures (e.g., anterior nuclear group, anteroventral nucleus (a.k.a. ventral anterior nucleus), anterodorsal nucleus, anteromedial nucleus, medial nuclear group, medial dorsal nucleus, midline nuclear group, paratenial nucleus, reuniens nucleus, rhomboidal nucleus, intralaminar nuclear group, centromedial nucleus, parafascicular nucleus, paracentral nucleus, central lateral nucleus, central medial nucleus, lateral nuclear group, lateral dorsal nucleus, lateral posterior nucleus, pulvinar, ventral nuclear group, ventral anterior nucleus, ventral lateral nucleus, ventral posterior nucleus, ventral posterior lateral nucleus, ventral posterior medial nucleus, metathalamus, medial geniculate body, lateral geniculate body, thalamic reticular nucleus, etc.), hypothalamus structures (e.g., anterior, medial area, parts of preoptic area, medial preoptic nucleus, suprachiasmatic nucleus, paraventricular nucleus, supraoptic nucleus (mainly), anterior hypothalamic nucleus, lateral area, parts of preoptic area, lateral preoptic nucleus, anterior part of lateral nucleus, part of supraoptic nucleus, other nuclei of preoptic area, median preoptic nucleus, periventricular preoptic nucleus, tuberal, medial area, dorsomedial hypothalamic nucleus, ventromedial nucleus, arcuate nucleus, lateral area, tuberal part of lateral nucleus, lateral tuberal nuclei, posterior, medial area, mammillary nuclei (part of mammillary bodies), posterior nucleus, lateral area, posterior part of lateral nucleus, optic chiasm, subfomical organ, periventricular nucleus, pituitary stalk, tuber cinereum, tuberal nucleus, tuberomammillary nucleus, tuberal region, mammillary bodies, mammillary nucleus, etc.), subthalamic structures (e.g., thalamic nucleus, zona incerta, etc.), pituitary gland structures (e.g., neurohypophysis, pars intermedia (intermediate lobe), adenohypophysis, etc.), telencephalon structures, white matter structures (e.g., corona radiate, internal capsule, external capsule, extreme capsule, arcuate fasciculus, uncinate fasciculus, perforant path, etc.), subcortical structures (e.g., hippocampus (medial temporal lobe), dentate gyrus, comu ammonis (CA fields), comu ammonis area 1, comu ammonis area 2, comu ammonis area 3, comu ammonis area 4, amygdala (limbic system) (limbic lobe), central nucleus (autonomic nervous system), medial nucleus (accessory olfactory system), cortical and basomedial nuclei (main olfactory system), lateral) and basolateral nuclei (frontotemporal cortical system), claustrum, basal ganglia, striatum, dorsal striatum (a.k.a. neostriatum), putamen, caudate nucleus, ventral striatum, nucleus accumbens, olfactory tubercle, globus pallidus (forms nucleus lentiformis with putamen), subthalamic nucleus, basal forebrain, anterior perforated substance, substantia innominata nucleus basalis, diagonal band of Broca, medial septal nuclei, etc.), rhinencephalon structures (e.g., olfactory bulb, piriform cortex, anterior olfactory nucleus, olfactory tract anterior commissure, uncus, etc.), cerebral cortex structures (e.g., frontal lobe, cortex, primary motor cortex (precentral gyrus, M1), supplementary motor cortex, premotor cortex, prefrontal cortex, gyri, superiorfrontal gyrus, middle frontal gyrus, interiorfrontal gyrus, Brodmann areas: 4, 6, 8, 9, 10, 11, 12, 24, 25, 32, 33, 44, 45, 46, 47, parietal lobe, cortex, primary somatosensory cortex (S1), secondary somatosensory cortex (S2), posterior parietal cortex, gyri, postcentral gyrus (primary somesthetic area), precuneus, Brodmann areas 1, 2, 3 (primary somesthetic area); 5, 7, 23, 26, 29, 31, 39, 40, occipital lobe, cortex, primary visual cortex (V1), V2, V3, V4, V5/MT, lateral occipital gyrus, cuneus, Brodmann areas 17 (V1 primary visual cortex); 18, 19, temporal lobe, primary auditory cortex (A1), secondary auditory cortex (A2), inferior temporal cortex, posterior inferior temporal cortex, superior temporal gyrus, middle temporal gyrus, inferior temporal gyrus, entorhinal cortex, perirhinal cortex, parahippocampal gyrus, fusiform gyrus, Brodmann areas: 9, 20, 21, 22, 27, 34, 35, 36, 37, 38, 41, 42, medial superiortemporal area (MST), insular cortex, cingulate cortex, anterior cingulate, Posterior cingulate, Retrosplenial cortex, Indusium griseum, Subgenual area 25, Brodmann areas 23, 24, 26, 29, 30 (retrosplenial areas); 31, 32, etc.).

The brain is the largest sex organ controlling the biological urge, mediating all thoughts, experiences and physiological responses to sex. The euphoric and pleasurable experience of sex stems primarily from the limbic system including the amygdala, hippocampus and limbic lobe (dentate and cingulate gyrus).

Neurons Neurons are electrically excitable cells that receive, process, and transmit information, and based on that information sends a signal to other neurons, muscles, a glands through electrical and chemical signals. These signals between neurons occur via specialized connections called synapses. Neurons can connect to each other to form neural networks. The basic purpose of a neuron is to receive incoming information and, based upon that information send a signal to other neurons, muscles, or glands. Neurons are designed to rapidly send signals across physiologically long distances. They do this using electrical signals called nerve impulses or action potentials. When a nerve impulse reaches the end of a neuron, it triggers the release of a chemical, or neurotransmitter. The neurotransmitter travels rapidly across the short gap between cells (the synapse) and acts to signal the adjacent cell. See www.biologyreference.com/Mo-Nu/Neuron.html#fxzz5AVxCuM5a.

Neurons can receive thousands of inputs from other neurons through synapses. Synaptic integration is a mechanism whereby neurons integrate these inputs before the generation of a nerve impulse, or action potential. The ability of synaptic inputs to effect neuronal output is determined by a number of factors: Size, shape and relative timing of electrical potentials generated by synaptic inputs; the geometric structure of the target neuron; the physical location of synaptic inputs within that structure; and the expression of voltage-gated channels in different regions of the neuronal membrane.

Neurons within a neural network receive information from, and send information to, many other cells, at specialized junctions called synapses. Synaptic integration is the computational process by which an individual neuron processes its synaptic inputs and converts them into an output signal. Synaptic potentials occur when neurotransmitter binds to and opens ligand-operated channels in the dendritic membrane, allowing ions to move into or out of the cell according to their electrochemical gradient. Synaptic potentials can be either excitatory or inhibitory depending on the direction and charge of ion movement. Action potentials occur if the summed synaptic inputs to a neuron reach a threshold level of depolarization and trigger regenerative opening of voltage-gated ion channels. Synaptic potentials are often brief and of small amplitude, therefore summation of inputs in time (temporal summation) or from multiple synaptic inputs (spatial summation) is usually required to reach action potential firing threshold.

There are two types of synapses: electrical synapses and chemical synapses. Electrical synapses are a direct electrical coupling between two cells mediated by gap junctions, which are pores constructed of connexin proteins—essentially result in the passing of a gradient potential (may be depolarizing or hyperpolarizing) between two cells. Electrical synapses are very rapid (no synaptic delay). It is a passive process where signal can degrade with distance and may not produce a large enough depolarization to initiate an action potential in the postsynaptic cell. Electrical synapses are bidirectional, i.e., postsynaptic cell can actually send messages to the “presynaptic cell.

Chemical synapses are a coupling between two cells through neuro-transmitters, ligand or voltage gated channels, receptors. They are influenced by the concentration and types of ions on either side of the membrane. Among the neurotransmitters, Glutamate, sodium, potassium, and calcium are positively charged. GABA and chloride are negatively charged. Neurotransmitter junctions provide an opportunity for pharmacological intervention, and many different drugs, including illicit drugs, act at synapses.

An excitatory postsynaptic potential (EPSP) is a postsynaptic potential that makes the postsynaptic neuron more likely to fire an action potential. An electrical charge (hyperpolarization) in the membrane of a postsynaptic neuron is caused by the binding of an inhibitory neurotransmitter from a presynaptic cell to a postsynaptic receptor. It makes it more difficult for a postsynaptic neuron to generate an action potential. An electrical change (depolarization) in the membrane of a postsynaptic neuron caused by the binding of an excitatory neurotransmitter from a presynaptic cell to a postsynaptic receptor. It makes it more likely for a postsynaptic neuron to generate an action potential. In a neuronal synapse that uses glutamate as receptor, for example, receptors open ion channels that are non-selectively permeable to cations. When these glutamate receptors are activated, both Na+ and K+ flow across the postsynaptic membrane. The reversal potential (Erev) for the post-synaptic current is approximately 0 mV. The resting potential of neurons is approximately −60 mV. The resulting EPSP will depolarize the postsynaptic membrane potential, bringing it toward 0 mV.

An inhibitory postsynaptic potential (IPSP) is a kind of synaptic potential that makes a postsynaptic neuron less likely to generate an action potential. An example of inhibitory postsynaptic action is a neuronal synapse that uses γ-Aminobutyric acid (GABA) as its transmitter. At such synapses, the GABA receptors typically open channels that are selectively permeable to Cl−. When these channels open, negatively charged chloride ions can flow across the membrane. The postsynaptic neuron has a resting potential of −60 mV and an action potential threshold of −40 mV. Transmitter release at this synapse will inhibit the postsynaptic cell. Since ECl is more negative than the action potential threshold, e.g., −70 mV, it reduces the probability that the postsynaptic cell will fire an action potential.

Some types of neurotransmitters, such as glutamate, consistently result in EPSPs. Others, such as GABA consistently result in IPSPs. The action potential lasts about one millisecond (1 msec). In contrast the EPSPs and IPSPs can last as long as 5 to 10 msec. This allows the effect of one postsynaptic potential to build upon the next and so on.

Membrane leakage, and to a lesser extent potentials per se, can be influenced by external electrical and magnetic fields. These fields may be generated locally, such as through implanted electrodes, or less specifically, such as through transcranial stimulation. Transcranial stimulation may be subthreshold or superthreshold. In the former case, the external stimulation acts to modulate resting membrane potential, making nerves more or less excitable. Such stimulation may be direct current or alternating current. In the latter case, this will tend to synchronize neuron depolarization with the signals. Superthreshold stimulation can be painful (at least because the stimulus directly excites pain neurons) and must be pulsed. Since this has correspondence to electroconvulsive therapy, superthreshold transcranial stimulation is sparingly used.

A number of neurotransmitters are known, as are pharmaceutical interventions and therapies that influence these compounds. Typically, the major neurotransmitters are small monoamine molecules, such as dopamine, epinephrine, norepinephrine, serotonin, GABA, histamine, etc., as well as acetylcholine. In addition, neurotransmitters also include amino acids, gas molecules such as nitric oxide, carbon monoxide, carbon dioxide, and hydrogen sulfide, as well as peptides. The presence, metabolism, and modulation of these molecules may influence learning and memory. Supply of neurotransmitter precursors, control of oxidative and mental stress conditions, and other influences on learning and memory-related brain chemistry, may be employed to facilitate memory, learning, and learning adaption transfer.

The neuropeptides, as well as their respective receptors, are widely distributed throughout the mammalian central nervous system. During learning and memory processes, besides structural synaptic remodeling, changes are observed at molecular and metabolic levels with the alterations in neurotransmitter and neuropeptide synthesis and release. While there is a consensus that brain cholinergic neurotransmission plays a critical role in the processes related to learning and memory, it is also well known that these functions are influenced by a tremendous number of neuropeptides and non-peptide molecules. Arginine vasopressin (AVP), oxytocin, angiotensin II, insulin, growth factors, serotonin (5-HT), melanin-concentrating hormone, histamine, bombesin and gastrin-releasing peptide (GRP), glucagon-like peptide-1 (GLP-1), cholecystokinin (CCK), dopamine, corticotropin-releasing factor (CRF) have modulatory effects on learning and memory. Among these peptides, CCK, 5-HT, and CRF play strategic roles in the modulation of memory processes under stressful conditions. CRF is accepted as the main neuropeptide involved in both physical and emotional stress, with a protective role during stress, possibly through the activation of the hypothalamo-pituitary (HPA) axis. The peptide CCK has been proposed to facilitate memory processing, and CCK-like immunoreactivity in the hypothalamus was observed upon stress exposure, suggesting that CCK may participate in the central control of stress response and stress-induced memory dysfunction. On the other hand, 5-HT appears to play a role in behaviors that involve a high cognitive demand and stress exposure activates serotonergic systems in a variety of brain regions. See:

Mehmetali Gülpinar, Berrak C Ye{hacek over (g)}en, “The Physiology of Learning and Memory Role of Peptides and Stress”, Current Protein and Peptide Science, 2004(5)

www.researchgate.net/publication/8147320_The_Physiology_of_Learning_and_Memory_Role_of_Peptides_and_Stress.Deep brain stimulation is described in NIH Research Matters, “A noninvasive deep brain stimulation technique”, (2017),

Brainworks, “QEEG Brain Mapping”.

Carmon, A., Mor, J., & Goldberg, J. (1976). Evoked cerebral responses to noxious thermal stimuli in humans. Experimental Brain Research, 25(1), 103-107.

Brainwaves At the root of all our thoughts, emotions and behaviors is the communication between neurons within our brains, a rhythmic or repetitive neural activity in the central nervous system. The oscillation can be produced by a single neuron a by synchronized electrical pulses from ensembles of neurons communicating with each other. The interaction between neurons can give rise to oscillations at a different frequency than the firing frequency of individual neurons. The synchronized activity of large numbers of neurons produces macroscopic oscillations, which can be observed in an electroencephalogram. They are divided into bandwidths to describe their purported functions or functional relationships. Oscillatory activity in the brain is widely observed at different levels of organization and is thought to play a key role in processing neural information. Numerous experimental studies support a functional role of neural oscillations. A unified interpretation, however, is still not determined. Neural oscillations and synchronization have been linked to many cognitive functions such as information transfer, perception, motor control and memory. Electroencephalographic (EEG) signals are relatively easy and safe to acquire, have a long history of analysis, and can have high dimensionality, e.g., up to 128 or 256 separate recording electrodes. While the information represented in each electrode is not independent of the others, and the noise in the signals high, there is much information available through such signals that has not been fully characterized to date.

Brainwaves have been widely studied in neural activity generated by large groups of neurons, mostly by EEG. In general, EEG signals reveal oscillatory activity (groups of neurons periodically firing in synchrony), in specific frequency bands: alpha (7.5-12.5 Hz) that can be detected from the occipital lobe during relaxed wakefulness and which increases when the eyes are closed; delta (1-4 Hz), theta (4-8 Hz), beta (13-30 Hz), low gamma (30-70 Hz), and high gamma (70-150 Hz) frequency bands, where faster rhythms such as gamma activity have been linked to cognitive processing. Higher frequencies imply multiple groups of neurons firing in coordination, either in parallel or in series, or both, since individual neurons do not fire at rates of 100 Hz. Neural oscillations of specific characteristics have been linked to cognitive states, such as awareness and consciousness and different sleep stages.

Nyquist Theorem states that the highest frequency that can be accurately represented is one-half of the sampling rate. Practically, the sampling rate should be ten times higher than the highest frequency of the signal. (See, www.slideshare.net/ertvk/eeg-examples). While EEG signals are largely band limited, the superimposed noise may not be. Further, the EEG signals themselves represent components from a large number of neurons, which fire independently. Therefore, large bandwidth signal acquisition may have utility.

It is a useful analogy to think of brainwaves as music. In orchestral music, where various instrument groups (string groups, such as violins, violas, cellos and double basses, brass, woodwind, and percussion instruments) produce particular sounds bases on their respective characteristic frequencies of vibrations that all come together in a musical composition. Similarly, in the brain, groups of neurons oscillate in unison producing specific frequencies that combine in brainwaves. Like in a symphony, the higher and lower frequencies link and cohere with each other through harmonics, especially when one considers that neurons may be coordinated not only based on transitions, but also on phase delay. Oscillatory activity is observed throughout the central nervous system at all levels of organization. Each respective mental state is associated with the dominant neuro oscillation frequency. Moreover, the nuances of each mental state may be associated with secondary and tertiary harmonics or, using musical analogy, the “overtones.” Some hypothesize that very slow brainwaves serve to synchronize various lobes and neuronal groups in the brain (similarly to law-frequency instruments, such as drums and double basses, serve to provide overall rhythm to the orchestra).

The functions of brainwaves are wide-ranging and vary for different types of oscillatory activity. Neural oscillations also play an important role in many neurological disorders.

Delta wave is the frequency range from 0.5 Hz to 4 Hz. It tends to be the highest in amplitude and the slowest waves (except for very-slow waves that have frequency less than 0.5 Hz). It is normally seen in adults in NREM (en.wikipedia.org/wiki/NREM). It is also seen normally in babies. It may occur focally with subcortical lesions and in general distribution with diffuse lesions, metabolic encephalopathy hydrocephalus or deep midline lesions. It is usually most prominent frontally in adults (e.g., FIRDA-frontal intermittent rhythmic delta) and posteriorly in children (e.g., OIRDA-occipital intermittent rhythmic delta).

Theta is the frequency range from 4 Hz to 7 Hz. Theta is normally seen in young children. It may be seen in drowsiness or arousal in older children and adults; it can also be seen in meditation. Excess theta for age represents abnormal activity. It can be seen as a focal disturbance in focal subcortical lesions; it can be seen in generalized distribution in diffuse disorder or metabolic encephalopathy or deep midline disorders or some instances of hydrocephalus. On the other hand, this range has been associated with reports of relaxed, meditative, and creative states.

Alpha is the frequency range from 7.5 Hz to 12.5 Hz. This is the “posterior basic rhythm” (also called the “posterior dominant rhythm,” the “posterior alpha rhythm” or the Berger's wave), arising from the synchronous and coherent electrical activity in the thalamic pacemaker cells and seen in the posterior regions of the head on both sides, higher in amplitude on the dominant side. They predominantly originate from the occipital lobe during wakeful relaxation with closed eyes. Alpha wave emerges with the closing of the eyes and with relaxation and attenuates with eye opening or mental exertion. The posterior basic rhythm is actually slower than 8 Hz in young children (therefore technically in the theta range). In addition to the posterior basic rhythm, there are other normal alpha rhythms such as the sensorimotor, or mu rhythm (alpha activity in the contralateral sensory and motor cortical areas) that emerges when the hands and arms are idle; and the “third rhythm” (alpha activity in the temporal or frontal lobes). Alpha can be abnormal; for example, an EEG that has diffuse alpha occurring in coma and is not responsive to external stimuli is referred to as “alpha coma.”

Beta is the frequency range from 15 Hz to about 30 Hz. It is usually seen on both sides in symmetrical distribution and is most evident frontally. Beta activity is closely linked to motor behavior and is generally attenuated during active movements. Low-amplitude beta with multiple and varying frequencies is often associated with active, busy or anxious thinking and active concentration. Rhythmic beta with a dominant set of frequencies is associated with various pathologies, such as Dup15q syndrome, and drug effects, especially benzodiazepines. It may be absent or reduced in areas of cortical damage. It is the dominant rhythm in patients who are alert or anxious or who have their eyes open.

Gamma is the frequency range approximately 250-100 Hz. Gamma rhythms are thought to represent binding of different populations of neurons together into a network to carry out a certain cognitive or motor function. Low gamma (25-70 Hz), and high gamma (70-150 Hz) frequency bands are also recognized with higher frequencies being associated with cognitive processing.

Mu range is 8-13 Hz and partly overlaps with other frequencies, but is generally considered one of the two types of alpha wave (the second type being the third rhythm). It reflects the synchronous firing of motor neurons in a rest state. Mu suppression is thought to reflect motor mirror neuron systems, because when an action is observed, the pattern extinguishes, possibly because of the normal neuronal system and the mirror neuron system “go out of sync” and interfere with each other. See:

Abeles M, Local Cortical Circuits (1982) New York: Springer-Verlag.

Braitenberg V and Schuz A (1991) Anatomy of the Cortex Statistics and Geometry. New York: Springer-Verlag.

Ebersole J S (1997) Defining epileptogenic foci: past present, future. J. Clin. Neurophysiology 14: 470-483.

Edelman G M and Tononi G (2000) A Universe of Consciousness, New York: Basic Books.

Freeman W J (1975) Mass Action in the Nervous System, New York: Academic Press.

Gevins A S and Cutillo B A (1995) Neuroelectric measures of mind. In: P L Nunez (Au), Neocortical Dynamics and Human EEG Rhythms. NY: Oxford U. Press, pp. 304-338.

Gevins A S, Le J, Martin N, Brickett P, Desmond J, and Reutler B (1994) High resolution EEG: 124-channel recording, spatial enhancement and MRI integration methods. Electroencephalography and Clin. Neurophysiology 90: 337-358.

Gevins A S, Smith M E, McEvoy L and Yu D (1997) High-resolution mapping of cortical activation related to working memory: effects of task difficulty, type of processing, and practice. Cerebral Cortex 7: 374-385.

Haken H (1983) Synergetics: An Introduction, 3rd Edition, Springer-Verlag.

Haken H (1999) What can synergetics contribute to the understanding of brain functioning? In: Analysis of Neurophysiological Brain Functioning, C Uhl (Ed), Berlin: Springer-Verlag, pp 7-40.

Ingber L (1995) Statistical mechanics of multiple scales of neocortical interactions. In: P L Nunez (Au), Neocortical Dynamics and Human EEG Rhythms. NY: Oxford U. Press, 628-681.

Izhikevich E M (1999) Weakly connected quasi-periodic oscillators, FM interactions, and multiplexing in the brain, SIAM J. Applied Mathematics 59: 2193-2223.

Jirsa V K and Haken H (1997) A derivation of a macroscopic field theory of the brain from the quasi-microscopic neural dynamics. Physica D 99: 503-526.

Jirsa V K and Kelso J A S (2000) Spatiotemporal pattern formation in continuous systems with heterogeneous connection topologies. Physical Review E 62: 8462-8465.

Katznelson R D (1981) Normal modes of the brain: Neuroanatomical basis and a physiological theoretical model. In PL Nunez (Au), Electric Fields of the Brain: The Neurophysics of EEG, 1st Edition, NY: Oxford U. Press, pp 401-442.

Klimesch W (1996) Memory processes, brain oscillations and EEG synchronization. International J. Psychophysiology 24: 61-100.

Law S K, Nunez P L and Wijesinghe R S (1993) High resolution EEG using spline generated surface Laplacians on spherical and ellipsoidal surfaces. IEEE Transactions on Biomedical Engineering 40: 145-153.

Liley D T J, Cadusch P J and Dafilis M P (2002) A spatially continuous mean field theory of electrocortical activity network. Computation in Neural Systems 13: 67-113.

Malmuvino J and Plonsey R (1995) Bioelectromagetism. NY: Oxford U. Press.

Niedermeyer E and Lopes da Silva F H (Eds) (2005) Electroencephalography. Basic Principals, Clin. Applications, and Related Fields. Fifth Edition. London: Williams and Wilkins.

Nunez P L (1989) Generation of human EEG by a combination of long and short range neocortical interactions. Brain Topography 1: 199-215.

Nunez P L (1995) Neocortical Dynamics and Human EEG Rhythms. NY: Oxford U. Press.

Nunez P L (2000) Toward a large-scale quantitative description of neocortical dynamic function and EEG (Target article), Behavioral and Brain Sciences 23: 371-398.

Nunez P L (2000) Neocortical dynamic theory should be as simple as possible, but not simpler (Response to 18 commentaries on target article), Behavioral and Brain Sciences 23: 415-437.

Nunez P L (2002) EEG. In VS Ramachandran (Ed) Encyclopedia of the Human Brain, La Jolla Academic Press, 169-179.

Nunez P L and Silberstein R B (2001) On the relationship of synaptic activity to macroscopic measurements: Does co-registration of EEG with fMRI make sense? Brain Topog. 13: 79-96.

Nunez P L and Srinivasan R (2006) Electric Fields of the Brain: The Neurophysics of EEG, 2nd Edition, NY: Oxford U. Press.

Nunez P L and Srinivasan R (2006) A theoretical basis for standing and traveling brain waves measured with human EEG with implications for an integrated consciousness. Clin. Neurophysiology 117: 2424-2435.

Nunez P L, Srinivasan R, Westdorp A F, Wjesinghe R S, Tucker D M, Silberstein R B, and Cadusch P J (1997) EEG coherency I: Statistics, reference electrode, volume conduction, Laplacians, cortical imaging, and interpretation at multiple scales. Electroencephalography and Clin. Neurophysiology 103: 516-527.

Nunez P L. Wingeier B M and Silberstein R B (2001) Spatial-temporal structures of human alpha rhythms: theory, micro-current sources, multiscale measurements, and global binding of local networks, Human Brain Mapping 13: 125-164.

Nuwer M (1997) Assessment of digital EEG, quantitative EEG, and EEG brain mapping: report of the American Academy of Neurology and the American Clin. Neurophysiology Society. Neurology 49: 277-292.

Penfield W and Jasper H D (1954) Epilepsy and the Functional Anatomy of the Human Brain. London: Little, Brown and Co.

Robinson P A Rennie C J, Rowe D L and O Conner S C (2004) Estimation of multiscale neurophysiologic parameters by electroencephalographic means. Human Brain Mapping 23: 53-72.

Scott A C (1995) Stairway to the Mind. New York: Springer-Verlag.

Silberstein R B, Danieli F and Nunez P L (2003) Fronto-parietal evoked potential synchronization is increased during mental rotation, NeuroReport 14: 67-71.

Silberstein R B, Song J, Nunez P L and Park W (2004) Dynamic sculpting of brain functional connectivity is correlated with performance, Brain Topography 16: 240-254.

Srinivasan R and Petrovic S (2006) MEG phase follows conscious perception during binocular rivalry induced by visual stream segregation. Cerebral Cortex, 16: 597-608.

Srinivasan R, Nunez P L and Silberstein R B (1998) Spatial filtering and neocortical dynamics: estimates of EEG coherence. IEEE Trans, on Biomedical Engineering, 45: 814-825.

Srinivasan R, Russell D P, Edelman G M, and Tononi G (1999) Frequency tagging competing stimuli in binocular rivalry reveals increased synchronization of neuromagnetic responses during conscious perception. J. Neuroscience 19: 5435-5448.

Uhl C (Ed) (1999) Analysis of Neurophysiological Brain Functioning. Berlin: Springer-Verlag,

Wingeier B M, Nunez P L and Silberstein R B (2001) Spherical harmonic decomposition applied to spatial-temporal analysis of human high-density electroencephalogram. Physical Review E 64: 051916-1 to 9.

en.wikipedia.org/wiki/Electroencephalography

TABLE 1
Comparison of EEG bands
Freq.
Band (Hz) Location Normally Pathologically
Delta <4 frontally in adults, adult slow-wave sleep subcortical lesions
posteriorly in in babies diffuse lesions
children; high- Has been found during metabolic encephalopathy hydrocephalus
amplitude waves some continuous- deep midline lesions
attention tasks
Theta 4-7  Found in locations higher in young children focal subcortical lesions
not related to task drowsiness in adults and metabolic encephalopathy
at hand teens deep midline disorders
idling some instances of hydrocephalus
Associated with inhibition
of elicited responses (has
been found to spike in
situations where a
person is actively trying to
repress a response or
action).
Alpha 7.5-12.5 posterior regions of relaxed/reflecting Coma
head, both sides, closing the eyes
higher in amplitude Also associated with
on dominant side. inhibition control,
Central sites seemingly with the
(c3-c4) at rest purpose of timing
inhibitory activity in
different locations across
the brain.
Beta 12.5-30   both sides, range span: active calm Benzodiazepines (en.wikipedia.org/wiki/Benzodiazepines)
symmetrical → intense→ stressed Dup15q syndrome
distribution, most → mild obsessive
evident frontally; active thinking, focus,
low-amplitude high alert, anxious
waves
Gamma 25-100 Somatosensory Displays during cross- A decrease in gamma-band activity may be associated with
cortex modal sensory cognitive decline, especially when related to the theta band;
processing (perception however, this has not been proven for use as a clinical diagnostic
that combines two measurement
different senses, such as
sound and sight)
Also is shown during
short-term memory
matching of recognized
objects, sounds, or tactile
sensations
Mu 8-12 Sensorimotor Shows rest-state motor Mu suppression could indicate that motor mirror neurons are
cortex neurons. working. Deficits in Mu suppression, and thus in mirror neurons,
might play a role in autism.

EEG AND qEEG An EEG electrode will mainly detect the neuronal activity in the brain region just beneath it. However, the electrodes receive the activity from thousands of neurons. One square millimeter of cortex surface, for example, has more than 100,000 neurons. It is only when the input to a region is synchronized with electrical activity occurring at the same time that simple periodic waveforms in the EEG become distinguishable. The temporal pattern associated with specific brainwaves can be digitized and encoded a non-transient memory, and embodied in a referenced by, computer software.

EEG (electroencephalography) and MEG (magnetoencephalography) are available technologies to monitor brain electrical activity. Each generally has sufficient temporal resolution to follow dynamic changes in brain electrical activity. Electroencephalography (EEG) and quantitative electroencephalography (qEEG) are electrophysiological monitoring methods that analyze the electrical activity of the brain to measure and display patterns that correspond to cognitive states and/or diagnostic information. It is typically noninvasive, with the electrodes placed on the scalp, although invasive electrodes are also used in some cases. EEG signals may be captured and analyzed by a mobile device, often referred as “brain wearables”. There are a variety of “brain wearables” readily available on the market today. EEGs can be obtained with a non-invasive method where the aggregate oscillations of brain electric potentials are recorded with numerous electrodes attached to the scalp of a person. Most EEG signals originate in the brain's outer layer (the cerebral cortex), believed largely responsible fix our thoughts, emotions, and behavior. Cortical synaptic action generates electrical signals that change in the 10 to 100-millisecond range. Transcutaneous EEG signals are limited by the relatively insulating nature of the skull surrounding the brain, the conductivity of the cerebrospinal fluid and brain tissue, relatively low amplitude of individual cellular electrical activity, and distances between the cellular current flows and the electrodes. EEG is characterized by (1) Voltage; (2) Frequency; (3) Spatial location; (4) Inter-hemispheric symmetries; (5) Reactivity (reaction to state change); (6) Character of waveform occurrence (random, serial, continuous); and (7) Morphology of transient events. EEGs can be separated into two main categories. Spontaneous EEG which occur in the absence of specific sensory stimuli and evoked potentials (EPs) which are associated with sensory stimuli like repeated light flashes, auditory tones, finger pressure or mild electric shocks. The latter is recorded for example by time averaging to remove effects of spontaneous EEG. Non-sensory triggered potentials are also known. EP's typically are time synchronized with the trigger, and thus have an organization principle. Event-related potentials (ERPs) provide evidence of a direct link between cognitive events and brain electrical activity in a wide range of cognitive paradigms. It has generally been held that an ERP is the result of a set of discrete stimulus-evoked brain events. Event-related potentials (ERPs) are recorded in the same way as EPs, but occur at longer latencies from the stimuli and are more associated with an endogenous brain state.

In standard EEG recording practice, 19 recording electrodes are placed uniformly on the scalp (the International 10-20 System). In addition, one a two reference electrodes (often placed on earlobes) and a ground electrode (often placed on the nose to provide amplifiers with reference voltages) are required. However, additional electrodes may add minimal useful information unless supplemented by computer algorithms to reduce raw EEG data to a manageable form. When large numbers of electrodes are employed, the potential at each location may be measured with respect to the average of all potentials (the common average reference), which often provides a good estimate of potential at infinity. The common average reference is not appropriate when electrode coverage is sparse (perhaps less than 64 electrodes). (See, Paul L. Nunez and Ramesh Srinivasan (2007) Electroencephalogram. Scholarpedia, 2(2):1348, scholarpedia.org/article/Electroencephalogram.Dipole localization algorithms may be useful to determine spatial emission patterns in EEG.)

Scalp potential may be expressed as a volume integral of dipole moment per unit volume over the entire brain provided P(r,t) defined generally rather than in columnar terms. For the important case of dominant cortical sources, scalp potential may be approximated by the following integral over the cortical volume Θ, VS(r,t)=∫∫∫ΘG(r,r′)·P(r′,t)dΘ(r′). If the volume element dΘ(r′) is defined in terms of cortical columns, the volume integral may be reduced to an integral over the folded cortical surface. The time-dependence of scalp potential is the weighted sum of all dipole time variations in the brain, although deep dipole volumes typically make negligible contributions. The vector Green's function G(r,r′) contains all geometric and conductive information about the head volume conductor and weights the integral accordingly. Thus, each scalar component of the Green's function is essentially an inverse electrical distance between each source component and scalp location. For the idealized case of sources in an infinite medium of constant conductivity, the electrical distance equals the geometric distance. The Green's function accounts for the tissue's finite spatial extent and its inhomogeneity and anisotropy. The forward problem in EEG consists of choosing a head model to provide G(r,r′) and carrying out the integral for some assumed source distribution. The inverse problem consists of using the recorded scalp potential distribution VS(r,t) plus some constraints (usual assumptions) on P(r,t) to find the best fit source distribution P(r,t). Since the inverse problem has no unique solution, any inverse solution depends critically on the chosen constraints, for example, only one or two isolated sources, distributed sources confined to the cortex, or spatial and temporal smoothness criteria. High-resolution EEG uses the experimental scalp potential VS(r,t) to predict the potential on the dura surface (the unfolded membrane surrounding the cerebral cortex) VD(r,t). This may be accomplished using a head model Green's function G(r,r′) or by estimating the surface Laplacian with either spherical a 3D splines. These two approaches typically provide very similar dura potentials VD(r,t); the estimates of dura potential distribution are unique subject to head model, electrode density, and noise issues.

In an EEG recording system, each electrode is connected to one input of a differential amplifier (one amplifier per pair of electrodes); a common system reference electrode (or synthesized reference) is connected to the other input of each differential amplifier. These amplifiers amplify the voltage between the active electrode and the reference (typically 1,000-100,000 times, or 60-100 dB of voltage gain). The amplified signal is digitized via an analog-to-digital converter, after being passed through an anti-aliasing filter. Analog-to-digital sampling typically occurs at 256-512 Hz in clinical scalp EEG; sampling rates of up to 20 kHz are used in some research applications. The EEG signals can be captured with open source hardware such as OpenBCI, and the signal can be processed by freely available EEG software such as EEGLAB or the Neurophysiological Biomarker Toolbox. A typical adult human EEG signal is about 10 μV to 100 μV in amplitude when measured from the scalp and is about 10-20 mV when measured from subdural electrodes.

Typically, a magnetic sensor with sufficient sensitivity to individual cell depolarization or small groups is a superconducting quantum interference device (SQIUD), which requires cryogenic temperature operation, either at liquid nitrogen temperatures (high temperature superconductors, HTS) or at liquid helium temperatures (low temperature superconductors, LTS). However, current research shows possible feasibility of room temperature superconductors (20C). Magnetic sensing has an advantage, due to the dipole nature of sources, of having better potential volumetric localization; however, due to this added information, complexity of signal analysis is increased.

In general, the electromagnetic signals detected represent action potentials, an automatic response of a nerve cell to depolarization beyond a threshold, which briefly opens conduction channels. The cells have ion pumps which seek to maintain a depolarized state. Once triggered, the action potential propagates along the membrane in two-dimensions, causing a brief high level of depolarizing ion flow. There is a quiescent period after depolarization that generally prevents oscillation within a single cell. Since the exon extends from the body of the neuron, the action potential will typically proceed along the length of the axon, which terminates in a synapse with another cell. While direct electrical connections between cells occur, often the axon releases a neurotransmitter compound into the synapse, which causes a depolarization or hyperpolarization of the target cell. Indeed, the result may also be release of a hormone or peptide, which may have a local or more distant effect.

The electrical fields detectable externally tend to not include signals which low frequency signals, such as static levels of polarization, or cumulative depolarizing or hyperpolarizing effects between action potentials. In myelinated tracts, the current flows at the segments tend to be small, and therefore the signals from individual cells are small. Therefore, the largest signal components are from the synapses and cell bodies. In the cerebrum and cerebellum, these structures are mainly in the cortex, which is largely near the skull, making electroencephalography useful, since it provides spatial discrimination based on electrode location. However, deep signals are attenuated, and poorly localized. Magnetoencephalography detects dipoles, which derive from current flow, rather than voltage changes. In the case of a radially or spherically symmetric current flow within a short distance, the dipoles will tend to cancel, while net current flows long axons will reinforce. Therefore, an electroencephalogram reads a different signal than a magnetoencephalogram.

EEG-based studies of emotional specificity at the single-electrode level demonstrated that asymmetric activity at the frontal site, especially in the alpha (8-12 Hz) band, is associated with emotion. Voluntary facial expressions of smiles of enjoyment produce higher left frontal activation. Decreased left frontal activity is observed during the voluntary facial expressions of fear. In addition to alpha band activity, theta band power at the frontal midline (Fm) has also been found to relate to emotional states. Pleasant (as opposed to unpleasant) emotions are associated with an increase in frontal midline theta power. Many studies have sought to utilize pattern classification, such as neural networks, statistical classifiers, clustering algorithms, etc., to differentiate between various emotional states reflected in EEG.

EEG-based studies of emotional specificity at the single-electrode level demonstrated that asymmetric activity at the frontal site, especially in the alpha (8-12 Hz) band, is associated with emotion. Ekman and Davidson found that voluntary facial expressions of smiles of enjoyment produced higher left frontal activation (Ekman P, Davidson R J (1993) Voluntary Smiling Changes Regional Brain Activity. Psychol Sci 4: 342-345). Another study by Coan et al. found decreased left frontal activity during the voluntary facial expressions of fear (Coan J A Allen J J, Harmon-Jones E (2001) Voluntary facial expression and hemispheric asymmetry over the frontal cortex. Psychophysiology 38: 912-925). In addition to alpha band activity, theta band power at the frontal midline (Fm) has also been found to relate to emotional states. Sammler and colleagues, for example, showed that pleasant (as opposed to unpleasant) emotion is associated with an increase in frontal midline theta power (Sammler D, Grigutsch M, Fritz T, Koelsch S (2007) Music and emotion: Electrophysiological correlates of the processing of pleasant and unpleasant music. Psychophysiology 44: 293-304). To further demonstrate whether these emotion-specific EEG characteristics are strong enough to differentiate between various emotional states, some studies have utilized a pattern classification analysis approach. See, for example:

Dan N, Xiao-Wei W, Li-Chen S, Bao-Liang L. EEG-based emotion recognition during watching movies; 2011 Apr. 27, 2011-May 1, 2011: 667-670;

Lin Y P, Wang C H, Jung T P, Wu T L, Jeng S K, et al. (2010) EEG-Based Emotion Recognition in Music Listening, Ieee T Bio Med Eng 57: 1798-1806;

Murugappan M, Nagarajan R, Yaacob S (2010) Classification of human emotion from EEG using discrete wavelet transform. J Biomed Sci Eng 3: 390-396;

Murugappan M, Nagarajan R, Yaacob S (2011) Combining Spatial Filtering and Wavelet Transform for Classifying Human Emotions Using EEG Signals. J Med. Bio. Eng. 31: 45-51.

Detecting different emotional states by EEG may be more appropriate using EEG-based functional connectivity. There are various ways to estimate EEG-based functional brain connectivity: correlation, coherence and phase synchronization indices between each pair of EEG electrodes had been used. The assumption is that a higher correlation map indicates a stronger relationship between two signals. (Brazier M A, Casby J U (1952) Cross-correlation and autocorrelation studies of electroencephalographic potentials. Electroen clin neuro 4: 201-211). Coherence gives information similar to correlation, but also includes the covariation between two signals as a function of frequency. (Cantero J L, Atienza M, Salas R M, Gomez C M (1999) Alpha EEG coherence in different brain states: an electrophysiological index of the arousal level in human subjects. Neurosci lett. 271: 167-70.) The assumption is that higher coherence indicates a stronger relationship between two signals. (Guevara M A Corsi-Cabrera M (1996) EEG coherence or EEG correlation? Int J Psychophysiology 23: 145-153; Cantero J L, Atienza M, Salas R M, Gomez C M (1999) Alpha EEG coherence in different brain states: an electrophysiological index of the arousal level in human subjects. Neurosci lett 271: 167-70; Adler G, Brassen S, Jajcevic A (2003) EEG coherence in Alzheimer's dementia J Neural Transm 110: 1051-1058; Deeny S P, Hillman C H, Janelle C M, Hatfield B D (2003) Cortico-cortical communication and superior performance in skilled marksmen: An EEG coherence analysis. J Sport Exercise Psy 25: 188-204.) Phase synchronization among the neuronal groups estimated based on the phase difference between two signals is another way to estimate the EEG-based functional connectivity among brain areas. It is. (Franaszczuk P J, Bergey G K (1999) An autoregressive method for the measurement of synchronization of interictal and ictal EEG signals. Biol Cybem 81: 3-9.)

A number of groups have examined emotional specificity using EEG-based functional brain connectivity. For example, Shin and Park showed that when emotional states become more negative at high room temperatures, correlation coefficients between the channels in temporal and occipital sites increase (Shin J-H, Park D-H. (2011) Analysis for Characteristics of Electroencephalogram (EEG) and Influence of Environmental Factors According to Emotional Changes. In Lee G, Howard D, Ślȩzak D, editors. Convergence and Hybrid Information Technology. Springer Berlin Heidelberg, 488-500.) Hinrichs and Machleidt demonstrated that coherence decreases in the alpha band during sadness, compared to happiness (Hinrichs H, Machleidt W (1992) Basic emotions reflected in EEG-coherences. Int J Psychophysiol 13: 225-232). Miskovic and Schmidt found that EEG coherence between the prefrontal cortex and the posterior cortex increased while viewing highly emotionally arousing (i.e., threatening) images, compared to viewing neutral images (Miskovic V, Schmidt L A (2010) Cross-regional cortical synchronization during affective image viewing. Brain Res 1362: 102-111). Costa and colleagues applied the synchronization index to detect interaction in different brain sites under different emotional states (Costa T, Rognoni E, Galati D (2006) EEG phase synchronization during emotional response to positive and negative film stimuli. Neurosci Lett 406: 159-164). Costa's results showed an overall increase in the synchronization index among frontal channels during emotional stimulation, particularly during negative emotion (i.e., sadness). Furthermore, phase synchronization patterns were found to differ between positive and negative emotions. Costa also found that sadness was more synchronized than happiness at each frequency band and was associated with a wider synchronization both between the right and left frontal sites and within the left hemisphere. In contrast happiness was associated with a wider synchronization between the frontal and occipital sites.

Different connectivity indices are sensitive to different characteristics of EEG signals. Correlation is sensitive to phase and polarity, but is independent of amplitudes. Changes in both amplitude and phase lead to a change in coherence (Guevara M A, Corsi-Cabrera M (1996) EEG coherence or EEG correlation? Int J Psychophysiol 23: 145-153). The phase synchronization index is only sensitive to a change in phase (Lachaux J P, Rodriguez E, Martinerie J, Varela F J (1999) Measuring phase synchrony in brain signals. Hum Brain Mapp 8: 194-208).

A number of studies have tried to classify emotional states by means of recording and statistically analyzing EEG signals from the central nervous systems. See for example:

Lin Y P, Wang C H, Jung T P, Wu T L, Jeng S K, et al. (2010) EEG-Based Emotion Recognition in Music Listening. IEEE T Bio Med Eng 57: 1798-1806

Murugappan M, Nagarajan R, Yaacob S (2010) Classification of human emotion from EEG using discrete wavelet transform. J Biomed Sci Eng 3: 390-396.

Murugappan M, Nagarajan R, Yaacob S (2011) Combining Spatial Filtering and Wavelet Transform for Classifying Human Emotions Using EEG Signals. J Med. Bio. Eng. 31: 45-51.

Berkman E, Wong D K, Guimaraes M P, Uy E T, Gross J J, et al. (2004) Brain wave recognition of emotions in EEG. Psychophysiology 41: S71-S71.

Chanel G, Kronegg J, Grandjean D, Pun T (2006) Emotion assessment Arousal evaluation using EEGs and peripheral physiological signals. Multimedia Content Representation, Classification and Security 4105: 530-537.

Hagiwara KlaM (2003) A Feeling Estimation System Using a Simple Electroencephalograph. IEEE International Conference on Systems, Man and Cybernetics. 4204-4209.

You-Yun Lee and Shulan Hsieh studied different emotional states by means of EEG-based functional connectivity patterns. They used emotional film clips to elicit three different emotional states.

The dimensional theory of emotion, which asserts that there are neutral, positive, and negative emotional states, may be used to classify emotional states, because numerous studies have suggested that the responses of the central nervous system correlate with emotional valence and arousal. As suggested by Mauss and Robins (2009), “measures of emotional responding appear to be structured along dimensions (e.g., valence, arousal) rather than discrete emotional states (e.g., sadness, fear, anger)”. See for example:

Davidson R J (1993) Cerebral Asymmetry and Emotion-Conceptual and Methodological Conundrums. Cognition Emotion 7: 115-138;

Jones N A, Fox N A (1992) Electroencephalogram asymmetry during emotionally evocative films and its relation to positive and negative affectivity. Brain Cogn 20: 280-299;

Schmidt L A, Trainor L J (2001) Frontal brain electrical activity (EEG) distinguishes valence and intensity of musical emotions. Cognition Emotion 15: 487-500;

Tomarken A J, Davidson R J, Henriques J B (1990) Resting frontal brain asymmetry predicts affective responses to films. J Pens Soc Psychol 59: 791-801.)

EEG-based functional connectivity change was found to be significantly different among emotional states of neutral, positive, or negative. Lee Y-Y, Hsieh S (2014) Classifying Different Emotional States by Means of EEG-Based Functional Connectivity Patterns. PLoS ONE 9(4): e95415. doi.org/10.1371/journal.pone.0095415. A connectivity pattern may be detected by pattern classification analysis using Quadratic Discriminant Analysis. The results indicated that the classification rate was better than chance. The authors found the following correlations:

Theta band. Compared to neutral emotions, a significantly lower correlation at the frontal site and higher correlations at the temporal and occipital sites were found when watching negative films. No differences between a negative state and a positive state were found in the theta band. A significantly lower correlation was found in a positive state than in a neutral state at the frontal and parietal sites. A positive state showed higher correlations than a neutral state mainly at the temporal, parietal and occipital sites.

Alpha band. A significantly higher correlation was found in a neutral state only in the case of F7-P7 activity. A negative state showed a significantly higher correlation than a positive state, especially at the parietal and occipital sites. A neutral state showed a lower correlation than a positive state mainly at the right temporal site.

Beta band. No significant difference in correlation was observed among emotional states in the beta band.

Gamma band. No significant difference in correlation was observed among emotional states in the gamma band.

They concluded that estimating EEG-based functional connectivity provides a useful tool for studying the relationship between brain activity and emotional states.

Emotions affect learning. Intelligent Tutoring Systems (ITS) learner model initially composed of a cognitive module was extended to include a psychological module and an emotional module. Alicia Heraz et al. introduced an emomental agent. It interacts with an ITS to communicate the emotional state of the learner based upon his mental state. The mental state was obtained from the learner's brainwaves. The agent learns to predict the learner's emotions by using ML techniques. (Alicia Heraz, Ryad Razaki; Claude Frasson, “Using machine learning to predict learner emotional state from brainwaves” Advanced Learning Technologies, 2007. ICALT 2007. Seventh IEEE International Conference on Advanced Learning Technologies (ICALT 2007)) See also:

Ella T. Mampusti, Jose S. Ng, Jarren James I. Quinto, Grizelda L. Teng, Merlin Teodosia C. Suarez, Rhia S. Trogo, “Measuring Academic Affective States of Students via Brainwave Signals”, Knowledge and Systems Engineering (KSE) 2011 Third International Conference on, pp. 226-231, 2011

Judith J. Azcarraga, John Francis Ibanez Jr., Ianne Robert Lim, Nestor Lumanas Jr., “Use of Personality Profile in Predicting Academic Emotion Based on Brainwaves Signals and Mouse Behavior”, Knowledge and Systems Engineering (KSE) 2011 Third International Conference on, pp. 239-244, 2011.

Yi-Hung Liu, Chien-Te Wu, Yung-Hwa Kao, Ya-Ting Chen, “Single-trial EEG-based emotion recognition using kernel Eigen-emotion pattern and adaptive support vector machine”, Engineering in Medicine and Biology Society (EMBC) 2013 35th Annual International Conference of the IEEE, pp. 4306-4309,2013, ISSN 1557-170X.

Thong Tri Vo, Nam Phuong Nguyen, Toi Vo Van, IFMBE Proceedings, vol. 63, pp. 621, 2018, ISSN 1680-0737, ISBN 978-981-10-4360-4.

Adrian Rodriguez Aguiñaga, Miguel Angel Lopez Ramirez, Lecture Notes in Computer Science, vol. 9456, pp. 177, 2015, ISSN 0302-9743, ISBN 978-3-319-26507-0.

Judith Azcarraga, Merlin Teodosia Suarez, “Recognizing Student Emotions using Brainwaves and Mouse Behavior Data”, International Journal of Distance Education Technologies, vol. 11, pp. 1,2013, ISSN 1539-3100.

Tri Thong Vo, Phuong Nam Nguyen, Van Toi Vo, IFMBE Proceedings, vol. 61, pp. 67, 2017, ISSN 1680-0737, ISBN 978-981-10-4219-5.

Alicia Heraz, Claude Frasson, Lecture Notes in Computer Science, vol. 5535, pp. 367, 2009, ISSN 0302-9743, ISBN 978-3-642-02246-3.

Hamwira Yaacob, Wahab Abdul, Norhaslinda Kamaruddin, “Classification of EEG signals using MLP based on categorical and dimensional perceptions of emotions”, Information and Communication Technology for the Muslim World (ICT4M) 2013 5th International Conference on, pp. 1-6, 2013.

Yuan-Pin Lin, Chi-Hong Wang, Tzyy-Ping Jung, Tien-Lin Wu, Shyh-Kang Jeng, Jeng-Ren Duann, Jyh-Homg Chen, “EEG-Based Emotion Recognition in Music Listening”, Biomedical Engineering IEEE Transactions on, vol. 57, pp. 1798-1806, 2010, ISSN 0018-9294.

Yi-Hung Liu, Wei-Teng Cheng, Yu-Tsung Hsiao, Chien-Te Wu, Mu-Der Jeng, “EEG-based emotion recognition based on kernel Fisher's discriminant analysis and spectral powers”, Systems Man and Cybernetics (SMC) 2014 IEEE International Conference on, pp. 2221-2225, 2014.

Using EEG to assess the emotional state has numerous practical applications. One of the first such applications was the development of a travel guide based on emotions by measuring brainwaves by the Singapore tourism group. “By studying the brainwaves of a family on vacation, the researchers drew up the Singapore Emotion Travel Guide, which advises future visitors of the emotions they can expect to experience at different attractions.” (www.lonelyplanet.com/news/2017/04/12/singapore-emotion-travel-guide) Joel Pearson at University of New South Wales and his group developed the protocol of measuring brainwaves of travelers using EEG and decoding specific emotional states.

Another recently released application pertains to virtual reality (VR) technology. On Sep. 18, 2017 Looxid Labs launched a technology that harnesses EEG from a subject wearing a VR headset Looxid Labs intention is to factor in brainwaves into VR applications in order to accurately infer emotions. Other products such as MindMaze and even Samsung have tried creating similar applications through facial muscles recognition. (scottamyx.com/2017/10/13/looxid-labs-vr-brain-waves-human-emotions/). According to its website (looxidlabs.com/device-2/), the Looxid Labs Development Kit provides a VR headset embedded with miniaturized eye and brain sensors. It uses 6 EEG channels: Fp1, Fp2, AF7, AF8, AF3, AF4 in international 10-20 system.

To assess a user's state of mind, a computer may be used to analyze the EEG signals produced by the brain of the user. However, the emotional states of a brain are complex, and the brainwaves associated with specific emotions seem to change over time. Wei-Long Zheng at Shanghai Jiao Tong University used machine learning (ML) to identify the emotional brain states and to repeat it reliably. The ML algorithm found a set of patterns that clearly distinguished positive, negative, and neutral emotions that worked for different subjects and for the same subjects overtime with an accuracy of about 80 percent (See Wei-Long Zheng, Jia-Yi Zhu, Bao-Liang Lu, Identifying Stable Patterns over Time for Emotion Recognition from EEG, arxiv.org/abs/1601.02197; see also How One Intelligent Machine Learned to Recognize Human Emotions, MIT Technology Review, Jan. 23, 2016.)

MEG Magnetoencephalography (MEG) is a functional neuroimaging technique for mapping brain activity by recording magnetic fields produced by electrical currents occurring naturally in the brain, using very sensitive magnetometers. Arrays of SQUIDs (superconducting quantum interference devices) are currently the most common magnetometer, while the SERF (spin exchange relaxation-tree) magnetometer is being investigated (Hämäläinen, Matti; Hari, Riitta; Ilmoniemi, Risto J; Knuutila, Jukka; Lounasmaa, Olli V. (1993). “Magnetoencephalography-theory, instrumentation, and applications to noninvasive studies of the working human brain”. Reviews of Modern Physics. 65 (2): 413-497. ISSN 0034-6861. doi: 10.1103/RevModPhys.65.413.) It is known that “neuronal activity causes local changes in cerebral blood flow, blood volume, and blood oxygenation” (Dynamic magnetic resonance imaging of human brain activity during primary sensory stimulation. K. K. Kwong, J. W. Belliveau, D. A Chester, I. E. Goldberg, R. M. Weisskoff, B. P. Poncelet D. N. Kennedy, B. E. Hoppel, M. S. Cohen, and R. Turner). Using “a 122-channel D.C. SQUID magnetometer with a helmet-shaped detector array covering the subject's head” it has been shown that the “system allows simultaneous recording of magnetic activity all over the head.” (122-channel squid instrument for investigating the magnetic signals from the human brain.) A. I. Ahonen, M. S. Hämäläinen, M. J. Kajola J. E. T. Knuutila P. P. Laine, O. V. Lounasmaa, L. T. Parkkonen, J. T. Simola, and C. D. Tesche Physica Scripta, Volume 1993, T49A).

In some cases, magnetic fields cancel, and thus the detectable electrical activity may fundamentally differ from the detectable electrical activity obtained via EEG. However, the main types of brain rhythms are detectable by both methods.

See: U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 5,059,814; 5,118,606; 5,136,687; 5,224,203; 5,303,705; 5,325,862; 5,461,699; 5,522,863; 5,640,493; 5,715,821; 5,719,561; 5,722,418; 5,730,146; 5,736,543; 5,737,485; 5,747,492; 5,791,342; 5,816,247; 6,497,658; 6,510,340; 6,654,729; 6,893,407; 6,950,697; 8,135,957; 8,620,206; 8,644,754; 9,118,775; 9,179,875; 9,642,552; 20030018278; 20030171689; 20060293578; 20070156457; 20070259323; 20080015458; 20080154148; 20080229408; 20100010365; 20100076334; 20100090835; 20120046531; 20120052905; 20130041281; 20150081299; 20150262016. See EP1304073A2; EP1304073A3; WO2000025668A1; and WO2001087153A1.

MEGs seek to detect the magnetic dipole emission from an electrical discharge in cells, e.g., neural action potentials. Typical sensors for MEGs are superconducting quantum interference devices (SQUIDs). These currently require coding to liquid nitrogen or liquid helium temperatures. However, the development of room temperature, or near room temperature superconductors, and miniature cryocoders, may permit field deployments and portable or mobile detectors. Because MEGs are less influenced by medium conductivity and dielectric properties, and because they inherently detect the magnetic field vector, MEG technology permits volumetric mapping of brain activity and distinction of complementary activity that might suppress detectable EEG signals. MEG technology also supports vector mapping of fields, since magnetic emitters are inherently dipoles, and therefore a larger amount of information is inherently available.

See, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 4,862,359; 5,027,817; 5,198,977; 5,230,346; 5,269,315; 5,309,923; 5,325,862; 5,331,970; 5,546,943; 5,568,816; 5,662,109; 5,724,987; 5,797,853; 5,840,040; 5,845,639; 6,042,548; 6,080,164; 6,088,611; 6,097,980; 6,144,872; 6,161,031; 6,171,239; 6,240,308; 6,241,686; 6,280,393; 6,309,361; 6,319,205; 6,322,515; 6,356,781; 6,370,414; 6,377,833; 6,385,479; 6,390,979; 6,402,689; 6,419,629; 6,466,816; 6,490,472; 6,526,297; 6,527,715; 6,530,884; 6,547,746; 6,551,243; 6,553,252; 6,622,036; 6,644,976; 6,648,880; 6,663,571; 6,684,098; 6,697,660; 6,728,564; 6,740,032; 6,743,167; 6,773,400; 6,907,280; 6,947,790; 6,950,698; 6,963,770; 6,963,771; 6,996,261; 7,010,340; 7,011,814; 7,022,083; 7,092,748; 7,104,947; 7,105,824; 7,120,486; 7,130,673; 7,171,252; 7,177,675; 7,231,245; 7,254,500; 7,283,861; 7,286,871; 7,338,455; 7,346,395; 7,378,056; 7,461,045; 7,489,964; 7,490,085; 7,499,745; 7,510,699; 7,539,528; 7,547,284; 7,565,193; 7,567,693; 7,577,472; 7,613,502; 7,627,370; 7,647,098; 7,653,433; 7,697,979; 7,729,755; 7,754,190; 7,756,568; 7,766,827; 7,769,431; 7,778,692; 7,787,937; 7,787,946; 7,794,403; 7,831,305; 7,840,250; 7,856,264; 7,860,552; 7,899,524; 7,904,139; 7,904,144; 7,933,645; 7,962,204; 7,983,740; 7,986,991; 8,000,773; 8,000,793; 8,002,553; 8,014,847; 8,036,434; 8,065,360; 8,069,125; 8,086,296; 8,121,694; 8,190,248; 8,190,264; 8,197,437; 8,224,433; 8,233,682; 8,233,965; 8,236,038; 8,262,714; 8,280,514; 8,295,914; 8,306,607; 8,306,610; 8,313,441; 8,326,433; 8,337,404; 8,346,331; 8,346,342; 8,356,004; 8,358,818; 8,364,271; 8,380,289; 8,380,290; 8,380,314; 8,391,942; 8,391,956; 8,423,125; 8,425,583; 8,429,225; 8,445,851; 8,457,746; 8,467,878; 8,473,024; 8,498,708; 8,509,879; 8,527,035; 8,532,756; 8,538,513; 8,543,189; 8,554,325; 8,562,951; 8,571,629; 8,586,932; 8,591,419; 8,606,349; 8,606,356; 8,615,479; 8,626,264; 8,626,301; 8,632,750; 8,644,910; 8,655,817; 8,657,756; 8,666,478; 8,679,009; 8,684,926; 8,690,748; 8,696,722; 8,706,205; 8,706,241; 8,706,518; 8,712,512; 8,717,430; 8,725,669; 8,738,395; 8,761,869; 8,761,889; 8,768,022; 8,805,516; 8,814,923; 8,831,731; 8,834,546; 8,838,227; 8,849,392; 8,849,632; 8,852,103; 8,855,773; 8,858,440; 8,868,174; 8,888,702; 8,915,741; 8,918,162; 8,938,289; 8,938,290; 8,951,189; 8,951,192; 8,956,277; 8,965,513; 8,977,362; 8,989,836; 8,998,828; 9,005,126; 9,020,576; 9,022,936; 9,026,217; 9,026,218; 9,028,412; 9,033,884; 9,037,224; 9,042,201; 9,050,470; 9,067,052; 9,072,905; 9,084,896; 9,089,400; 9,089,683; 9,092,556; 9,095,266; 9,101,276; 9,107,595; 9,116,835; 9,133,024; 9,144,392; 9,149,255; 9,155,521; 9,167,970; 9,167,976; 9,167,977; 9,167,978; 9,171,366; 9,173,609; 9,179,850; 9,179,854; 9,179,858; 9,179,875; 9,192,300; 9,198,637; 9,198,707; 9,204,835; 9,211,077; 9,211,212; 9,213,074; 9,242,067; 9,247,890; 9,247,924; 9,248,288; 9,254,097; 9,254,383; 9,268,014; 9,268,015; 9,271,651; 9,271,674; 9,282,930; 9,289,143; 9,302,110; 9,308,372; 9,320,449; 9,322,895; 9,326,742; 9,332,939; 9,336,611; 9,339,227; 9,357,941; 9,367,131; 9,370,309; 9,375,145; 9,375,564; 9,387,320; 9,395,425; 9,402,558; 9,403,038; 9,414,029; 9,436,989; 9,440,064; 9,463,327; 9,470,728; 9,471,978; 9,474,852; 9,486,632; 9,492,313; 9,560,967; 9,579,048; 9,592,409; 9,597,493; 9,597,494; 9,615,789; 9,616,166; 9,655,573; 9,655,669; 9,662,049; 9,662,492; 9,669,185; 9,675,292; 9,682,232; 9,687,187; 9,707,396; 9,713,433; 9,713,444; 20010020127; 20010021800; 20010051774; 20020005784; 20020016552; 20020017994; 20020042563; 20020058867; 20020099273; 20020099295; 20020103428; 20020103429; 20020128638; 20030001098; 20030009096; 20030013981; 20030032870; 20030040660; 20030068605; 20030074032; 20030093004; 20030093005; 20030120140; 20030128801; 20030135128; 20030153818; 20030163027; 20030163028; 20030181821; 20030187359; 20030204135; 20030225335; 20030236458; 20040030585; 20040059241; 20040072133; 20040077960; 20040092809; 20040096395; 20040097802; 20040116798; 20040122787; 20040122790; 20040144925; 20040204656; 20050004489; 20050007091; 20050027284; 20050033122; 20050033154; 20050033379; 20050079474; 20050079636; 20050106713; 20050107654; 20050119547; 20050131311; 20050136002; 20050159670; 20050159671; 20050182456; 20050192514; 20050222639; 20050283053; 20060004422; 20060015034; 20060018525; 20060036152; 20060036153; 20060051814; 20060052706; 20060058683; 20060074290; 20060074298; 20060078183; 20060084858; 20060100526; 20060111644; 20060116556; 20060122481; 20060129324; 20060173510; 20060189866; 20060241373; 20060241382; 20070005115; 20070007454; 20070008172; 20070015985; 20070032737; 20070055145; 20070100251; 20070138886; 20070179534; 20070184507; 20070191704; 20070191727; 20070203401; 20070239059; 20070250138; 20070255135; 20070293760; 20070299370; 20080001600; 20080021332; 20080021340; 20080033297; 20080039698; 20080039737; 20080042067; 20080058664; 20080091118; 20080097197; 20080123927; 20080125669; 20080128626; 20080154126; 20080167571; 20080221441; 20080230702; 20080230705; 20080249430; 20080255949; 20080275340; 20080306365; 20080311549; 20090012387; 20090018407; 20090018431; 20090018462; 20090024050; 20090048507; 20090054788; 20090054800; 20090054958; 20090062676; 20090078875; 20090082829; 20090099627; 20090112117; 20090112273; 20090112277; 20090112278; 20090112279; 20090112280; 20090118622; 20090131995; 20090137923; 20090156907; 20090156955; 20090157323; 20090157481; 20090157482; 20090157625; 20090157662; 20090157751; 20090157813; 20090163777; 20090164131; 20090164132; 20090171164; 20090172540; 20090177050; 20090179642; 20090191131; 20090209845; 20090216091; 20090220429; 20090221928; 20090221930; 20090246138; 20090264785; 20090267758; 20090270694; 20090287271; 20090287272; 20090287273; 20090287274; 20090287467; 20090292180; 20090292713; 20090292724; 20090299169; 20090304582; 20090306531; 20090306534; 20090318773; 20090318794; 20100021378; 20100030073; 20100036233; 20100036453; 20100041962; 20100042011; 20100049276; 20100069739; 20100069777; 20100076274; 20100082506; 20100087719; 20100094154; 20100094155; 20100099975; 20100106043; 20100113959; 20100114193; 20100114237; 20100130869; 20100143256; 20100163027; 20100163028; 20100163035; 20100168525; 20100168529; 20100168602; 20100189318; 20100191095; 20100191124; 20100204748; 20100248275; 20100249573; 20100261993; 20100298735; 20100324441; 20110004115; 20110004412; 20110009777; 20110015515; 20110015539; 20110028859; 20110034821; 20110046491; 20110054345; 20110054562; 20110077503; 20110092800; 20110092882; 20110112394; 20110112426; 20110119212; 20110125048; 20110125238; 20110129129; 20110144521; 20110160543; 20110160607; 20110160608; 20110161011; 20110178359; 20110178441; 20110178442; 20110207988; 20110208094; 20110213200; 20110218405; 20110230738; 20110257517; 20110263962; 20110263968; 20110270074; 20110270914; 20110275927; 20110295143; 20110295166; 20110301448; 20110306845; 20110306846; 20110307029; 20110313268; 20110313487; 20120004561; 20120021394; 20120022343; 20120022884; 20120035765; 20120046531; 20120046971; 20120053449; 20120053483; 20120078327; 20120083700; 20120108998; 20120130228; 20120130229; 20120149042; 20120150545; 20120163689; 20120165899; 20120165904; 20120197163; 20120215114; 20120219507; 20120226091; 20120226185; 20120232327; 20120232433; 20120245493; 20120253219; 20120253434; 20120265267; 20120271148; 20120271151; 20120271376; 20120283502; 20120283604; 20120296241; 20120296253; 20120296569; 20120302867; 20120310107; 20120310298; 20120316793; 20130012804; 20130063434; 20130066350; 20130066391; 20130066394; 20130072780; 20130079621; 20130085678; 20130096441; 20130096454; 20130102897; 20130109996; 20130110616; 20130116561; 20130131755; 20130138177; 20130172716; 20130178693; 20130184728; 20130188854; 20130204085; 20130211238; 20130226261; 20130231580; 20130238063; 20130245422; 20130245424; 20130245486; 20130261506; 20130274586; 20130281879; 20130281890; 20130289386; 20130304153; 20140000630; 20140005518; 20140031703; 20140057232; 20140058241; 20140058292; 20140066763; 20140081115; 20140088377; 20140094719; 20140094720; 20140111335; 20140114207; 20140119621; 20140128763; 20140135642; 20140148657; 20140151563; 20140155952; 20140163328; 20140163368; 20140163409; 20140171749; 20140171757; 20140171819; 20140180088; 20140180092; 20140180093; 20140180094; 20140180095; 20140180096; 20140180097; 20140180099; 20140180100; 20140180112; 20140180113; 20140180176; 20140180177; 20140193336; 20140194726; 20140200414; 20140211593; 20140228649; 20140228702; 20140243614; 20140243652; 20140243714; 20140249360; 20140249445; 20140257073; 20140270438; 20140275807; 20140275851; 20140275891; 20140276013; 20140276014; 20140276187; 20140276702; 20140279746; 20140296646; 20140296655; 20140303425; 20140303486; 20140316248; 20140323849; 20140330268; 20140330394; 20140335489; 20140336489; 20140340084; 20140343397; 20140357962; 20140364721; 20140371573; 20140378830; 20140378941; 20150011866; 20150011877; 20150018665; 20150018905; 20150024356; 20150025408; 20150025422; 20150025610; 20150029087; 20150033245; 20150033258; 20150033259; 20150033262; 20150033266; 20150035959; 20150038812; 20150038822; 20150038869; 20150039066; 20150073237; 20150080753; 20150088120; 20150119658; 20150119689; 20150119698; 20150140528; 20150141529; 20150141773; 20150150473; 20150151142; 20150157266; 20150165239; 20150174418; 20150182417; 20150196800; 20150201879; 20150208994; 20150219732; 20150223721; 20150227702; 20150230744; 20150246238; 20150247921; 20150257700; 20150290420; 20150297106; 20150297893; 20150305799; 20150305800; 20150305801; 20150306340; 20150313540; 20150317796; 20150320591; 20150327813; 20150335281; 20150335294; 20150339363; 20150343242; 20150359431; 20150360039; 20160001065; 20160001096; 20160001098; 20160008620; 20160008632; 20160015289; 20160022165; 20160022167; 20160022168; 20160022206; 20160027342; 20160029946; 20160029965; 20160038049; 20160038559; 20160048659; 20160051161; 20160051162; 20160058354; 20160058392; 20160066828; 20160066838; 20160081613; 20160100769; 20160120480; 20160128864; 20160143541; 20160143574; 20160151018; 20160151628; 20160157828; 20160158553; 20160166219; 20160184599; 20160196393; 20160199241; 20160203597; 20160206380; 20160206871; 20160206877; 20160213276; 20160235324; 20160235980; 20160235983; 20160239966; 20160239968; 20160245670; 20160245766; 20160270723; 20160278687; 20160287118; 20160287436; 20160296746; 20160302720; 20160303397; 20160303402; 20160320210; 20160339243; 20160341684; 20160361534; 20160366462; 20160371721; 20170021161; 20170027539; 20170032098; 20170039706; 20170042474; 20170043167; 20170065349; 20170079538; 20170080320; 20170085855; 20170086729; 20170086763; 20170087367; 20170091418; 20170112403; 20170112427; 20170112446; 20170112577; 20170147578; 20170151435; 20170160360; 20170164861; 20170164862; 20170164893; 20170164894; 20170172527; 20170173262; 20170185714; 20170188862; 20170188866; 20170188868; 20170188869; 20170188932; 20170189691; 20170196501; and 20170202633.

Allen, Philip B., et al. High-temperature superconductivity. Springer Science & Business Media, 2012;

Fausti, Daniele, et al. “Light-induced superconductivity in a stripe-ordered cuprate.” Science 331.6014 (2011): 189-191;

Inoue, Mitsuteru, et al. “Investigating the use of magnonic crystals as extremely sensitive magnetic field sensors at room temperature.” Applied Physics Letters 98.13 (2011): 132511;

Kaiser, Stefan, et al. “Optically induced coherent transport far above Tc in underdoped YBa2Cu3O6+δ.” Physical Review B 89.18 (2014): 184516;

Malik, M. A, and B. A Malik. “High Temperature Superconductivity: Materials, Mechanism and Applications.” Bulgarian J. Physics 41.4 (2014).

Mankowsky, Roman, et al. “Nonlinear lattice dynamics as a basis for enhanced superconductivity in YBa2Cu3O6.5.” arXiv preprint arXiv:1405.2266 (2014);

Mcfetridge, Grant “Room temperature superconductor.” U.S. Pub. App. No. 20020006875.

Mitrano, Matteo, et al. “Possible light-induced superconductivity in K3C60 at high temperature.” Nature 530.7591 (2016): 461-464;

Mourachkine, Andrei. Room-temperature superconductivity. Cambridge Int Science Publishing, 2004;

Narlikar, Anant V., ed. High Temperature Superconductivity 2. Springer Science & Business Media, 2013;

Pickett, Warren E. “Design for a room-temperature superconductor.” J. superconductivity and novel magnetism 19.3 (2006): 291-297;

Sleight, Arthur W. “Room temperature superconductors.” Accounts of chemical research 28.3 (1995): 103-108.

Hämäläinen, Matti; Hari, Riitta; Ilmoniemi, Risto J; Knutila, Jukka; Lounasmaa, Olli V. (1993). “Magnetoencephalography-theory, instrumentation, and applications to noninvasive studies of the working human brain”. Reviews of Modern Physics. 65 (2): 413-497. ISSN 0034-6861. doi:10.1103/RevModPhys.65.413.

EEGs and MEGs can monitor the state of consciousness. For example, states of deep sleep are associated with slower EEG oscillations of larger amplitude. Various signal analysis methods allow for robust identifications of distinct sleep stages, depth of anesthesia, epileptic seizures and connections to detailed cognitive events.

Positron Emission Tomography (PET) Scan A PET scan is an imaging test that helps reveal how tissues and organs are functioning (Bailey, D. L; D. W. Townsend; P. E. Valk; M. N. Maisey (2005). Positron Emission Tomography Basic Sciences. Secaucus, N.J.: Springer-Verlag. ISBN 1-85233-798-2). A PET scan uses a radioactive drug (positron-emitting tracer) to show this activity. It uses this radiation to produce 3-D, images colored for the different activity of the brain. See, e.g.:

Janden, Jens O., Vijay Dhawan, Alexander Poltorak, Jerome B. Posner, and David A Rottenbeng. “Positron emission tomographic measurement of blood-to-brain and blood-to-tumor transport of 82Rb: The effect of dexamethasone and whole-brain radiation therapy.” Annals of neurology 18, no. 6 (1985): 636-646.

Dhawan, V. I. J. A. Y., A Poltorak, J. R. Moeller, J. O. Janden, S. C. Strother, H. Thaler, and D. A. Rotlenberg. “Positron emission tomographic measurement of blood-to-brain and blood-to-tumour transport of 82Rb. I: Error analysis and computer simulations.” Physics in medicine and biology 34, no. 12 (1989): 1773.

U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 4,977,505; 5,331,970; 5,568,816; 5,724,987; 5,825,830; 5,840,040; 5,845,639; 6,053,739; 6,132,724; 6,161,031; 6,226,418; 6,240,308; 6,266,453; 6,364,845; 6,408,107; 6,490,472; 6,547,746; 6,615,158; 6,633,686; 6,644,976; 6,728,424; 6,775,405; 6,885,886; 6,947,790; 6,996,549; 7,117,026; 7,127,100; 7,150,717; 7,254,500; 7,309,315; 7,355,597; 7,367,807; 7,383,237; 7,483,747; 7,583,857; 7,627,370; 7,647,098; 7,678,047; 7,738,683; 7,778,490; 7,787,946; 7,876,938; 7,884,101; 7,890,155; 7,901,211; 7,904,144; 7,961,922; 7,983,762; 7,986,991; 8,002,553; 8,069,125; 8,090,164; 8,099,299; 8,121,361; 8,126,228; 8,126,243; 8,148,417; 8,148,418; 8,150,796; 8,160,317; 8,167,826; 8,170,315; 8,170,347; 8,175,359; 8,175,360; 8,175,686; 8,180,125; 8,180,148; 8,185,186; 8,195,593; 8,199,982; 8,199,985; 8,233,689; 8,233,965; 8,249,815; 8,303,636; 8,306,610; 8,311,747; 8,311,748; 8,311,750; 8,315,812; 8,315,813; 8,315,814; 8,321,150; 8,356,004; 8,358,818; 8,374,411; 8,379,947; 8,386,188; 8,388,529; 8,423,118; 8,430,816; 8,463,006; 8,473,024; 8,496,594; 8,520,974; 8,523,779; 8,538,108; 8,571,293; 8,574,279; 8,577,103; 8,588,486; 8,588,552; 8,594,950; 8,606,356; 8,606,361; 8,606,530; 8,606,592; 8,615,479; 8,630,812; 8,634,616; 8,657,756; 8,664,258; 8,675,936; 8,675,983; 8,680,119; 8,690,748; 8,706,518; 8,724,871; 8,725,669; 8,734,356; 8,734,357; 8,738,395; 8,754,238; 8,768,022; 8,768,431; 8,785,441; 8,787,637; 8,795,175; 8,812,245; 8,812,246; 8,838,201; 8,838,227; 8,861,819; 8,868,174; 8,871,797; 8,913,810; 8,915,741; 8,918,162; 8,934,685; 8,938,102; 8,980,891; 8,989,836; 9,025,845; 9,034,911; 9,037,224; 9,042,201; 9,053,534; 9,064,036; 9,076,212; 9,078,564; 9,081,882; 9,082,169; 9,087,147; 9,095,266; 9,138,175; 9,144,392; 9,149,197; 9,152,757; 9,167,974; 9,171,353; 9,171,366; 9,177,379; 9,177,416; 9,179,854; 9,186,510; 9,198,612; 9,198,624; 9,204,835; 9,208,430; 9,208,557; 9,211,077; 9,221,755; 9,226,672; 9,235,679; 9,256,982; 9,268,902; 9,271,657; 9,273,035; 9,275,451; 9,282,930; 9,292,858; 9,295,838; 9,305,376; 9,311,335; 9,320,449; 9,328,107; 9,339,200; 9,339,227; 9,367,131; 9,370,309; 9,390,233; 9,396,533; 9,401,021; 9,402,558; 9,412,076; 9,418,368; 9,434,692; 9,436,989; 9,449,147; 9,451,303; 9,471,978; 9,472,000; 9,483,613; 9,495,684; 9,556,149; 9,558,558; 9,560,967; 9,563,950; 9,567,327; 9,582,152; 9,585,723; 9,600,138; 9,600,778; 9,604,056; 9,607,377; 9,613,186; 9,652,871; 9,662,083; 9,697,330; 9,706,925; 9,717,461; 9,729,252; 9,732,039; 9,734,589; 9,734,601; 9,734,632; 9,740,710; 9,740,946; 9,741,114; 9,743,835; RE45336; RE45337; 20020032375; 20020183607; 20030013981; 20030028348; 20030031357; 20030032870; 20030068605; 20030128801; 20030233039; 20030233250; 20030234781; 20040049124; 20040072133; 20040116798; 20040151368; 20040184024; 20050007091; 20050065412; 20050080124; 20050096311; 20050118286; 20050144042; 20050215889; 20050244045; 20060015153; 20060074290; 20060084858; 20060129324; 20060188134; 20070019846; 20070032737; 20070036402; 20070072857; 20070078134; 20070081712; 20070100251; 20070127793; 20070280508; 20080021340; 20080069446; 20080123927; 20080167571; 20080219917; 20080221441; 20080241804; 20080247618; 20080249430; 20080279436; 20080281238; 20080286453; 20080287774; 20080287821; 20080298653; 20080298659; 20080310697; 20080317317; 20090018407; 20090024050; 20090036781; 20090048507; 20090054800; 20090074279; 20090099783; 20090143654; 20090148019; 20090156907; 20090156955; 20090157323; 20090157481; 20090157482; 20090157625; 20090157660; 20090157751; 20090157813; 20090163777; 20090164131; 20090164132; 20090164302; 20090164401; 20090164403; 20090164458; 20090164503; 20090164549; 20090171164; 20090172540; 20090221904; 20090246138; 20090264785; 20090267758; 20090270694; 20090271011; 20090271120; 20090271122; 20090271347; 20090290772; 20090292180; 20090292478; 20090292551; 20090299435; 20090312595; 20090312668; 20090316968; 20090316969; 20090318773; 20100004762; 20100010316; 20100010363; 20100014730; 20100014732; 20100015583; 20100017001; 20100022820; 20100030089; 20100036233; 20100041958; 20100041962; 20100041964; 20100042011; 20100042578; 20100063368; 20100069724; 20100069777; 20100076249; 20100080432; 20100081860; 20100081861; 20100094155; 20100100036; 20100125561; 20100130811; 20100130878; 20100135556; 20100142774; 20100163027; 20100163028; 20100163035; 20100168525; 20100168529; 20100168602; 20100172567; 20100179415; 20100189318; 20100191124; 20100219820; 20100241449; 20100249573; 20100260402; 20100268057; 20100268108; 20100274577; 20100274578; 20100280332; 20100293002; 20100305962; 20100305963; 20100312579; 20100322488; 20100322497; 20110028825; 20110035231; 20110038850; 20110046451; 20110077503; 20110125048; 20110152729; 20110160543; 20110229005; 20110230755; 20110263962; 20110293193; 20120035765; 20120041318; 20120041319; 20120041320; 20120041321; 20120041322; 20120041323; 20120041324; 20120041498; 20120041735; 20120041739; 20120053919; 20120053921; 20120059246; 20120070044; 20120080305; 20120128683; 20120150516; 20120207362; 20120226185; 20120263393; 20120283502; 20120288143; 20120302867; 20120316793; 20120321152; 20120321160; 20120323108; 20130018596; 20130028496; 20130054214; 20130058548; 20130063434; 20130064438; 20130066618; 20130085678; 20130102877; 20130102907; 20130116540; 20130144192; 20130151163; 20130188830; 20130197401; 20130211728; 20130226464; 20130231580; 20130237541; 20130243287; 20130245422; 20130274586; 20130318546; 20140003696; 20140005518; 20140018649; 20140029830; 20140058189; 20140063054; 20140063055; 20140067740; 20140081115; 20140107935; 20140119621; 20140133720; 20140133722; 20140148693; 20140155770; 20140163627; 20140171757; 20140194726; 20140207432; 20140211593; 20140222113; 20140222406; 20140226888; 20140236492; 20140243663; 20140247970; 20140249791; 20140249792; 20140257073; 20140270438; 20140343397; 20140348412; 20140350380; 20140355859; 20140371573; 20150010223; 20150012466; 20150019241; 20150029087; 20150033245; 20150033258; 20150033259; 20150033262; 20150033266; 20150073141; 20150073722; 20150080753; 20150088015; 20150088478; 20150150530; 20150150753; 20150157266; 20150161326; 20150161348; 20150174418; 20150196800; 20150199121; 20150201849; 20150216762; 20150227793; 20150257700; 20150272448; 20150287223; 20150294445; 20150297106; 20150306340; 20150317796; 20150324545; 20150327813; 20150332015; 20150335303; 20150339459; 20150343242; 20150363941; 20150379230; 20160004396; 20160004821; 20160004957; 20160007945; 20160019693; 20160027178; 20160027342; 20160035093; 20160038049; 20160038770; 20160048965; 20160067496; 20160070436; 20160073991; 20160082319; 20160110517; 20160110866; 20160110867; 20160113528; 20160113726; 20160117815; 20160117816; 20160117819; 20160128661; 20160133015; 20160140313; 20160140707; 20160151018; 20160155005; 20160166205; 20160180055; 20160203597; 20160213947; 20160217586; 20160217595; 20160232667; 20160235324; 20160239966; 20160239968; 20160246939; 20160263380; 20160284082; 20160296287; 20160300352; 20160302720; 20160364859; 20160364860; 20160364861; 20160366462; 20160367209; 20160371455; 20160374990; 20170024886; 20170027539; 20170032524; 20170032527; 20170032544; 20170039706; 20170053092; 20170061589; 20170076452; 20170085855; 20170091418; 20170112577; 20170128032; 20170147578; 20170148213; 20170168566; 20170178340; 20170193161; 20170198349; 20170202621; 20170213339; 20170216595; 20170221206; and 20170231560.

fMRI Functional magnetic resonance imaging or functional MRI (fMRI) is a functional neuroimaging procedure using MRI technology that measures brain activity by detecting changes associated with blood flow (“Magnetic Resonance, a critical peer-reviewed introduction; functional MRI”. European Magnetic Resonance Forum. Retrieved 17 Nov. 2014; Huetlel, Song & McCarthy (2009)).

Yukiyasu Kamitani et al., Neuron (DOI: 10.1016/j. neuron.2008.11.004) used an image of brain activity taken in a functional MRI scanner to recreate a black-and-white image from scratch. See also “Mind-reading” software could record your dreams” By Celeste Biever. New Scientist 12 Dec. 2008. (www.newscientist/com/article/dn16267-mind-reading software-could-record-your-dreams/)

See, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 6,622,036; 7,120,486; 7,177,675; 7,209,788; 7,489,964; 7,697,979; 7,754,190; 7,856,264; 7,873,411; 7,962,204; 8,060,181; 8,224,433; 8,315,962; 8,320,649; 8,326,433; 8,356,004; 8,380,314; 8,386,312; 8,392,253; 8,532,756; 8,562,951; 8,626,264; 8,632,750; 8,655,817; 8,679,009; 8,684,742; 8,684,926; 8,698,639; 8,706,241; 8,725,669; 8,831,731; 8,849,632; 8,855,773; 8,868,174; 8,915,871; 8,918,162; 8,939,903; 8,951,189; 8,951,192; 9,026,217; 9,037,224; 9,042,201; 9,050,470; 9,072,905; 9,084,896; 9,095,266; 9,101,276; 9,101,279; 9,135,221; 9,161,715; 9,192,300; 9,230,065; 9,248,286; 9,248,288; 9,265,458; 9,265,974; 9,292,471; 9,296,382; 9,302,110; 9,308,372; 9,345,412; 9,367,131; 9,420,970; 9,440,646; 9,451,899; 9,454,646; 9,463,327; 9,468,541; 9,474,481; 9,475,502; 9,489,854; 9,505,402; 9,538,948; 9,579,247; 9,579,457; 9,615,746; 9,693,724; 9,693,734; 9,694,155; 9,713,433; 9,713,444; 20030093129; 20030135128; 20040059241; 20050131311; 20050240253; 20060015034; 20060074822; 20060129324; 20060161218; 20060167564; 20060189899; 20060241718; 20070179534; 20070244387; 20080009772; 20080091118; 20080125669; 20080228239; 20090006001; 20090009284; 20090030930; 20090062676; 20090062679; 20090082829; 20090132275; 20090137923; 20090157662; 20090164132; 20090209845; 20090216091; 20090220429; 20090270754; 20090287271; 20090287272; 20090287273; 20090287467; 20090290767; 20090292713; 20090297000; 20090312808; 20090312817; 20090312998; 20090318773; 20090326604; 20090327068; 20100036233; 20100049276; 20100076274; 20100094154; 20100143256; 20100145215; 20100191124; 20100298735; 20110004412; 20110028827; 20110034821; 20110092882; 20110106750; 20110119212; 20110256520; 20110306845; 20110306846; 20110313268; 20110313487; 20120035428; 20120035765; 20120052469; 20120060851; 20120083668; 20120108909; 20120165696; 20120203725; 20120212353; 20120226185; 20120253219; 20120265267; 20120271376; 20120296569; 20130031038; 20130063550; 20130080127; 20130085678; 20130130799; 20130131755; 20130158883; 20130185145; 20130218053; 20130226261; 20130226408; 20130245886; 20130253363; 20130338803; 20140058528; 20140114889; 20140135642; 20140142654; 20140154650; 20140163328; 20140163409; 20140171757; 20140200414; 20140200432; 20140211593; 20140214335; 20140243652; 20140276549; 20140279746; 20140309881; 20140315169; 20140347265; 20140371984; 20150024356; 20150029087; 20150033245; 20150033258; 20150033259; 20150033262; 20150033266; 20150038812; 20150080753; 20150094962; 20150112899; 20150119658; 20150164431; 20150174362; 20150174418; 20150196800; 20150227702; 20150248470; 20150257700; 20150290453; 20150290454; 20150297893; 20150305685; 20150324692; 20150327813; 20150339363; 20150343242; 20150351655; 20150359431; 20150360039; 20150366482; 20160015307; 20160027342; 20160031479; 20160038049; 20160048659; 20160051161; 20160051162; 20160055304; 20160107653; 20160120437; 20160144175; 20160152233; 20160158553; 20160206380; 20160213276; 20160262680; 20160263318; 20160302711; 20160306942; 20160324457; 20160357256; 20160366462; 20170027812; 20170031440; 20170032098; 20170042474; 20170043160; 20170043167; 20170061034; 20170065349; 20170085547; 20170086727; 20170087302; 20170091418; 20170113046; 20170188876; 20170196501; 20170202476; 20170202518; and 20170206913.

Functional Near Infrared Spectroscopy (fNIRS) fNIR is a non-invasive imaging method involving the quantification of chromophore concentration resolved from the measurement of near infrared (NIR) light attenuation or temporal or phasic changes. NIR spectrum light takes advantage of the optical window in which skin, tissue, and bone are mostly transparent to NIR light in the spectrum of 700-900 nm, while hemoglobin (Hb) and deoxygenated-hemoglobin (deoxy-Hb) are stronger absorbers of light. Differences in the absorption spectra of deoxy-Hb and oxy-Hb allow the measurement of relative changes in hemoglobin concentration through the use of light attenuation at multiple wavelengths. Two or more wavelengths are selected, with one wavelength above and one below the isosbestic point of 810 nm at which deoxy-Hb and oxy-Hb have identical absorption coefficients. Using the modified Beer-Lambert law (mBLL), relative concentration can be calculated as a function of total photon path length. Typically, the light emitter and detector are placed ipsilaterally on the subject's skull so recorded measurements are due to back-scattered (reflected) light following elliptical pathways. The use of fNIR as a functional imaging method relies on the principle of neuro-vascular coupling also known as the hemodynamic response or blood-oxygen-level dependent (BOLD) response. This principle also forms the core of fMRI techniques. Through neurovascular coupling, neuronal activity is linked to related changes in localized cerebral blood flow. fNIR and fMRI are sensitive to similar physiologic changes and are often comparative methods. Studies relating fMRI and fNIR show highly correlated results in cognitive tasks. fNIR has several advantages in cost and portability over fMRI, but cannot be used to measure cortical activity more than 4 cm deep due to limitations in light emitter power and has more limited spatial resolution. fNIR includes the use of diffuse optical tomography (DOT/NIRDOT) for functional purposes. Multiplexing fNIRS channels can allow 2D topographic functional maps of brain activity (e.g. with Hitachi ETG4000 or Artinis Oxymon) while using multiple emitter spacings may be used to build 3D tomographic maps.

Beste Yuksel and Robert Jacob, Brain Automated Chorales (BACh), ACM CHI 2016, DOI: 10.1145/2858036.2858388, provides a system that helps beginners learn to play Bach chorales on piano by measuring how hard their brains are working. This is accomplished by estimating the brain's workload using functional Near-Infrared Spectroscopy (fNIRS), a technique that measures oxygen levels in the brain—in this case in the prefrontal cortex. A brain that's working hard pulls in more oxygen. Sensors strapped to the player's forehead talk to a computer, which delivers the new music, one line at a time. See also “Mind-reading tech helps beginners quickly learn to play Bach.” By Anna Nowogrodzki, New Scientist, 9 Feb. 2016 available online at www.newscientist.com/article/207689-mind-reading-tech-helps-beginners-quickly-learn-to-play-bach/.

LORETA Low-resolution brain electromagnetic tomography often referred as LORETA is a functional imaging technology usually using a linearly constrained minimum variance vector beamformer in the time-frequency domain as described in Gross et al., “Dynamic imaging of coherent sources: Studying neural interactions in the human brain,” PNAS 98, 694-699, 2001. It allows to the image (mostly 3D) evoked and induced oscillatory activity in a variable time-frequency range, where time is taken relative to a triggered event. There are three categories of imaging related to the technique used for LORETA. See, wiki.besa.de/index.php?title=Source_Analysis_3D_Imaging#Multile_Source_Beamformer_.28MSBF.29. The Multiple Source Beamformer (MSBF) is a tool for imaging brain activity. It is applied in the time-frequency domain and based on single-trial data. Therefore, it can image not only evoked, but also induced activity, which is not visible in time-domain averages of the data. Dynamic Imaging of Coherent Sources (DICS) can find coherence between any two pairs of voxels in the brain a between an external source and brain voxels. DICS requires time-frequency-transformed data and can find coherence for evoked and induced activity. The following imaging methods provides an image of brain activity based on a distributed multiple source model: CLARA is an iterative application of LORETA images, focusing the obtained 3D image in each iteration step. LAURA uses a spatial weighting function that has the form of a local autoregressive function. LORETA has the 3D Laplacian operator implemented as spatial weighting prior. sLORETA is an unweighted minimum norm that is standardized by the resolution matrix swLORETA is equivalent to sLORETA except for an additional depth weighting. SSLOFO is an iterative application of standardized minimum norm images with consecutive shrinkage of the source space. A User-defined volume image allows experimenting with the different imaging techniques. It is possible to specify user-defined parameters for the family of distributed source images to create a new imaging technique. If no individual MRI is available, the minimum norm image is displayed on a standard brain surface and computed for standard source locations. If available, an individual brain surface is used to construct the distributed source model and to image the brain activity. Unlike classical LORETA, cortical LORETA is not computed in a 3D volume, but on the cortical surface. Unlike classical CLARA, cortical CLARA is not computed in a 3D volume, but on the cortical surface. The Multiple Source Probe Scan (MSPS) is a tool for the validation of a discrete multiple source model. The Source Sensitivity image displays the sensitivity of a selected source in the current discrete source model and is, therefore, data independent.

See U.S. Pat. Nos. and Pat. Appl. Nos.: U.S. Pat. Nos. 4,562,540; 4,594,662; 5,650,726; 5,859,533; 6,026,173; 6,182,013; 6,294,917; 6,332,087; 6,393,363; 6,534,986; 6,703,838; 6,791,331; 6,856,830; 6,863,127; 7,030,617; 7,092,748; 7,119,553; 7,170,294; 7,239,731; 7,276,916; 7,286,871; 7,295,019; 7,353,065; 7,363,164; 7,454,243; 7,499,894; 7,648,498; 7,804,441; 7,809,434; 7,841,986; 7,852,087; 7,937,222; 8,000,795; 8,046,076; 8,131,526; 8,174,430; 8,188,749; 8,244,341; 8,263,574; 8,332,191; 8,346,365; 8,362,780; 8,456,166; 8,538,700; 8,565,883; 8,593,154; 8,600,513; 8,706,205; 8,711,655; 8,731,987; 8,756,017; 8,761,438; 8,812,237; 8,829,908; 8,958,882; 9,008,970; 9,035,657; 9,069,097; 9,072,449; 9,091,785; 9,092,895; 9,121,964; 9,133,709; 9,165,472; 9,179,854; 9,320,451; 9,367,738; 9,414,749; 9,414,763; 9,414,764; 9,442,088; 9,468,541; 9,513,398; 9,545,225; 9,557,439; 9,562,988; 9,568,635; 9,651,706; 9,675,254; 9,675,255; 9,675,292; 9,713,433; 9,715,032; 20020000808; 20020017905; 20030018277; 20030093004; 20040097802; 20040116798; 20040131998; 20040140811; 20040145370; 20050156602; 20060058856; 20060069059; 20060136135; 20060149160; 20060152227; 20060170424; 20060176062; 20060184058; 20060206108; 20070060974; 20070159185; 20070191727; 20080033513; 20080097235; 20080125830; 20080125831; 20080183072; 20080242976; 20080255816; 20080281667; 20090039889; 20090054801; 20090082688; 20090099783; 20090216146; 20090261832; 20090306534; 20090312663; 20100010366; 20100030097; 20100042011; 20100056276; 20100092934; 20100132448; 20100134113; 20100168053; 20100198519; 20100231221; 20100238763; 20110004115; 20110050232; 20110160607; 20110308789; 20120010493; 20120011927; 20120016430; 20120083690; 20120130641; 20120150257; 20120162002; 20120215448; 20120245474; 20120268272; 20120269385; 20120296569; 20130091941; 20130096408; 20130141103; 20130231709; 20130289385; 20130303934; 20140015852; 20140025133; 20140058528; 20140066739; 20140107519; 20140128763; 20140155740; 20140161352; 20140163328; 20140163893; 20140228702; 20140243714; 20140275944; 20140276012; 20140323899; 20150051663; 20150112409; 20150119689; 20150137817; 20150145519; 20150157235; 20150167459; 20150177413; 20150248615; 20150257648; 20150257649; 20150301218; 20150342472; 20160002523; 20160038049; 20160040514; 20160051161; 20160051162; 20160091448; 20160102500; 20160120436; 20160136427; 20160187524; 20160213276; 20160220821; 20160223703; 20160235983; 20160245952; 20160256109; 20160259085; 20160262623; 20160298449; 20160334534; 20160345856; 20160356911; 20160367812; 20170001016; 20170067323; 20170138132; and 20170151436.

Neurofeedback Neurofeedback (NFB), also called neurotherapy or neurobiofeedback, is a type of biofeedback that uses real-time displays of brain activity-frost commonly electroencephalography (EEG), to teach self-regulation of brain function. Typically, sensors are placed on the scalp to measure activity, with measurements displayed using video displays or sound. The feedback may be in various other forms as well. Typically, the feedback is sought to be presented through primary sensory inputs, but this is not a limitation on the technique.

The applications of neurofeedback to enhance performance extend to the arts in fields such as music, dance, and acting. A study with conservatoire musicians found that alpha-theta training benefitted the three music domains of musicality, communication, and technique. Historically, alpha-theta training, a form of neurofeedback, was created to assist creativity by inducing hypnagogia, a “borderline waking state associated with creative insights”, through facilitation of neural connectivity. Alpha-theta training has also been shown to improve novice singing in children. Alpha-theta neurofeedback, in conjunction with heart rate variability training, a form of biofeedback, has also produced benefits in dance by enhancing performance in competitive ballroom dancing and increasing cognitive creativity in contemporary dancers. Additionally, neurofeedback has also been shown to instill a superior flow state in actors, possibly due to greater immersion while performing.

Several studies of brain wave activity in experts while performing a task related to their respective area of expertise revealed certain characteristic telltale signs of so-called “flow” associated with top-flight performance. Mihaly Csikszeritmihalyi (University of Chicago) found that the most skilled chess players showed less EEG activity in the prefrontal cortex, which is typically associated with higher cognitive processes such as working memory and verbalization, during a game.

Chris Berka et al., Advanced Brain Monitoring, Carlsbad, Calif., The International J. Sport and Society, vol 1, p 87, looked at the brainwaves of Olympic archers and professional golfers. A few seconds before the archers fired off an arrow or the golfers hit the ball, the team spotted a small increase in alpha band patterns. This may correspond to the contingent negative variation observed in evoked potential studies, and the Bereitschaftspotential or BP (from German, “readiness potential”), also called the pre-motor potential or readiness potential (RP), a measure of activity in the motor cortex and supplementary motor area of the brain leading up to voluntary muscle movement. Berka also trained novice marksmen using neurofeedback. Each person was hooked up to electrodes that tease out and display specific brainwaves, along with a monitor that measured their heartbeat. By controlling their breathing and learning to deliberately manipulate the waveforms on the screen in front of them, the novices managed to produce the alpha waves characteristic of the flow state. This, in turn, helped them improve their accuracy at hitting the targets.

Low Energy Neurofeedback System (LENS) The LENS, a Low Energy Neurofeedback System, uses a very low power electromagnetic field, to carry feedback ID the person receiving it. The feedback travels down the same wires carrying the brainwaves to the amplifier and computer. Although the feedback signal is weak, it produces a measurable change in the brainwaves without conscious effort from the individual receiving the feedback. The system is software controlled, to receive input from EEG electrodes, to control the stimulation. Through the scalp. Neurofeedback uses a feedback frequency that is different from, but correlates with, the dominant brainwave frequency. When exposed to this feedback frequency, the EEG amplitude distribution changes in power. Most of the time the brainwaves reduce in power; but at times they also increase in power. In either case the result is a changed brainwave state, and much greater ability for the brain to regulate itself.

Content-Based Brainwave Analysis Memories are not unique. Janice Chen, Nature Neuroscience, DOI: 10.1038/nn.4450, showed that when people describe the episode from Sherlock Holmes drama, their brain activity patterns were almost exactly the same as each other's, for each scene. Moreover, there's also evidence that, when a person tells someone else about it, they implant that same activity into their brain as well. Moreover, research in which people who have not seen a movie listen to someone else's description of it, Chen et al. have found that the listener's brain activity looks much like that of the person who has seen it. See also “Our brains record and remember things in exactly the same way” by Andy Coghlan, New Scientist, Dec. 5, 2016 (www.newscientist.com/article/2115093-our-brains-record-and-remember-things-in-exactly-the-same-way/)

Brian Pasley, Frontiers in Neuroengineering, doi.org/whb, developed a technique for reading thoughts. The team hypothesized that hearing speech and thinking to oneself might spark some of the same neural signatures in the brain. They supposed that an algorithm trained to identify speech heard out loud might also be able to identify words that are thought. In the experiment, the decoder trained on speech was able to reconstruct which words several of the volunteers were thinking, using neural activity alone. See also “Hearing our inner voice” by Helen Thomson. New Scientist Oct. 29, 2014 (www.newscientist.com/article/mg22429934-000-brain-decoder-can-eavesdrop-on-your-inner-voice/)

Jack Gallant et al. were able to detect which of a set of images someone was looking at from a brain scan, using software that compared the subject's brain activity while looking at an image with that captured while they were looking at “training” photographs. The program then picked the most likely match from a set of previously unseen pictures.

Ann Graybiel and Mark Howe used electrodes to analyze brainwaves in the ventromedial striatum of rats while they were taught to navigate a maze. As rats were learning the task, their brain activity showed bursts of fast gamma waves. Once the rats mastered the task, their brainwaves slowed to almost a quarter of their initial frequency, becoming beta waves. Graybiel's team posited that this transition reflects when learning becomes a habit.

Bernard Balleine, Proceedings of the National Academy of Sciences, DOI: 10.1073/pnas.1113158108. See also “Habits form when brainwaves slow down” by Wendy Zukerman. New Scientist, Sep. 26, 2011 (www.newscientist.com/article/dn20964-habits-from-when-brainwaves-slow-down/) posits that the slower brainwaves may be the brain weeding out excess activity to refine behavior. He suggests it might be possible to boost the rate at which they learn a skill by enhancing such beta-wave activity.

U.S. Pat. No. 9,763,592 provides a system for instructing a user behavior change comprising: collecting and analyzing bioelectrical signal datasets; and providing a behavior change suggestion based upon the analysis. A stimulus may be provided to prompt an action by the user, which may be visual, auditory, a haptic. See also U.S. Pat. No. 9,622,660, 20170041699; 20130317384; 20130317382; 20130314243; 20070173733; and 20070066914.

The chess game is a good example of a cognitive task which needs a lot of training and experience. A number of EEG studies have been done on chess players. Pawel Stepien, Wlodzimierz Klonowski and Nikolay Suvorov, Nonlinear analysis of EEG in chess players, EPJ Nonlinear Biomedical Physics 20153:1, showed better applicability of Higuchi Fractal Dimension method for analysis of EEG signals related to chess tasks than that of Sliding Window Empirical Mode Decomposition. The paper shows that the EEG signal during the game is more complex, non-linear, and non-stationary even when there are no significant differences between the game and relaxed state in the contribution of different EEG bands to total power of the signal. There is the need of gathering more data from more chess experts and of comparing them with data from novice chess players. See also Junior, L. R. S., Cesar, F. H. G., Rocha, F. T., and Thomaz, C. E. EEG and Eye Movement Maps of Chess Players. Proceedings of the Sixth International Conference on Pattern Recognition Applications and Methods. (ICPRAM 2017) pp. 343441. (fei.edu.br/˜cet/icpram17_LaercioJunior.pdf).

Estimating EEG-based functional connectivity provides a useful tool for studying the relationship between brain activity and emotional states. See You-Yun Lee, Shulan Hsieh. Classifying Different Emotional States by Means of EEG-Based Functional Connectivity Patterns. Apr. 17, 2014, (doi.org/10.1371/journal.pone.0095415), which aimed to classify different emotional states by means of EEG-based functional connectivity patterns, and showed that the EEG-based functional connectivity change was significantly different among emotional states. Furthermore, the connectivity pattern was detected by pattern classification analysis using Quadratic Discriminant Analysis. The results indicated that the classification rate was better than chance. Estimating EEG-based functional connectivity provides a useful tool for studying the relationship between brain activity and emotional states.

Neuromodulation/Neuroenhancement Neuromodulation is the alteration of nerve activity through targeted delivery of a stimulus, such as electrical stimulation or chemical agents, to specific neurological sites in the body. It is carried out to normalize—or modulate—nervous tissue function. Neuromodulation is an evolving therapy that can involve a range of electromagnetic stimuli such as a magnetic field (TMS, rTMS), an electric current (TES, e.g., tDCS, HD-tDCS, tACS, osc-tDCS, electrosleep), or a drug instilled directly in the subdural space (intrathecal drug delivery). Emerging applications involve targeted introduction of genes or gene regulators and light (optogenetics). The most clinical experience has been with electrical stimulation. Neuromodulation, whether electrical or magnetic, employs the body's natural biological response by stimulating nerve cell activity that can influence populations of nerves by releasing transmitters, such as dopamine, or other chemical messengers such as the peptide Substance P, that can modulate the excitability and firing patterns of neural circuits. There may also be more direct electrophysiological effects on neural membranes. According to some applications, the end effect is a “normalization” of a neural network function from its perturbed state. Presumed mechanisms of action for neurostimulation include depolarizing blockade, stochastic normalization of neural firing, axonal blockade, reduction of neural firing keratosis, and suppression of neural network oscillations. Although the exact mechanisms of neurostimulation are not entirely clear, the empirical effectiveness has led to considerable application clinically.

Neuroenhancement refers to the targeted enhancement and extension of cognitive, affective, and motor abilities based on an understanding of their underlying neurobiology in healthy persons who do not have any mental illness. As such, it can be thought of as an umbrella term that encompasses pharmacological and non-pharmacological methods of improving cognitive, affective, and motor functionality. Critically, for any agent to qualify as a neuroenhancer, it must reliably engender substantial cognitive, affective, or motor benefits beyond normal functioning in healthy individuals (or in select groups of individuals having pathology), while causing few side effects: at most at the level of commonly used comparable legal substances or activities, such as caffeine, alcohol, and sleep-deprivation. Pharmacological neuroenhancement agents include the well-validated nootropics, such as racetam, vinpocetine, and phosphatidylserine, as well as other drugs used for treating patients suffering from neurological disorders. Non-pharmacological measures include non-invasive brain stimulation, which has been employed to improve various cognitive and affective functions, and brain-machine interfaces, which hold much potential to extend the repertoire of motor and cognitive actions available to humans.

Brain Stimulation The entrainment hypothesis, suggests the possibility of inducing a particular oscillation frequency in the brain using an external oscillatory force (e.g., rTMS, tDCS, tACS, binaural beats, isochronic tones, light stimulation). The physiological basis of oscillatory cortical activity lies in the timing of the interacting neurons; when groups of neurons synchronize their firing activities, brain rhythms emerge, network oscillations are generated, and the basis for interactions between brain areas may develop. Synchronization of spatially separated lobes of the brain may also play a role. Because of the variety of experimental protocols for brain stimulation, limits on descriptions of the actual protocols employed, and limited controls, consistency of reported studies is lacking, and extrapolability is limited. Thus, while there is some consensus in various aspects of the effects of extra cranial brain stimulation, the results achieved have a degree of uncertainty dependent on details of implementation. On the other hand, within a specific experimental protocol, it is possible to obtain statistically significant and repeatable results. This implies that feedback control might be effective to control implementation of the stimulation for a given purpose; however, prior studies that employ feedback control are lacking.

Changes in the neuronal threshold result from changes in membrane permeability (Liebetanz et al., 2002), which influence the response of the task-related network. The same mechanism of action may be responsible for both TES methods and TMS, i.e., the induction of noise in the system. However, the neural activity induced by TES will be highly influenced by the state of the system because it is a neuromodulatory method (Paulus, 2011), and its effect will depend on the activity of the stimulated area. Therefore, the final result will depend strongly on the task characteristics, the system state and the way in which TES will interact with such a state.

In TMS, the magnetic pulse causes a rapid increase in current flow, which can in some cases cause and above-threshold depolarization of cell membranes affected by the current triggering an action potential, and leading to the trans-synaptic depolarization or hyperpolarization of connected cortical neurons, depending on their natural response to the firing of the stimulated neuron(s). Therefore, TMS activates a neural population that, depending on several factors, can be congruent (facilitate) or incongruent (inhibit) with task execution. TES induces a polarization of cortical neurons at a subthreshold level that is too weak to evoke an action potential. However, by inducing a polarity shift in the intrinsic neuronal excitability, TES can alter the spontaneous firing rate of neurons and modulate the response to afferent signals. In this sense, TES-induced effects are even more bound to the state of the stimulated area that is determined by the conditions. In short, NIBS leads to a stimulation-induced modulation of the state that can be substantially defined as noise induction. Induced noise will not be just random activity, but will depend on the interaction of many parameters, from the characteristics of the stimulation to the state.

The noise induced by NIBS will be influenced by the state of the neural population of the stimulated area. Although the types and number of neurons “triggered” by NIBS are theoretically random, the induced change in neuronal activity is likely to be correlated with ongoing activity, yet even if we are referring to a non-deterministic process, the noise introduced will not be a totally random element. Because it will be partially determined by the experimental variables, the level of noise that will be introduced by the stimulation and by the context can be estimated, as well as the interaction between the two levels of noise (stimulation and context). Although, HD-tDCS made a significantly more focused spatial application of TES possible, generally, known transcranial stimulation does not permit stimulation with a focused and highly targeted signal to a clearly defined area of the brain to establish a unique brain-behavior relationship; therefore, the known introduced stimulus activity in the brain stimulation is ‘noise.’

Cosmetic neuroscience has emerged as a new field of research. Roy Hamilton, Samuel Messing, and Anjan Chatterjee, “Rethinking the thinking cap—Ethics of neural enhancement using noninvasive brain stimulation.” Neurology, Jan. 11, 2011, vol. 76 no. 2 187-193. (www.neurology.org/content/76/2/187.) discuss the use noninvasive brain stimulation techniques such as transcranial magnetic stimulation and transcranial direct current stimulation to enhance neurologic function: cognitive skills, mood, and social cognition.

Electrical brain stimulation (EBS), also known as, focal brain stimulation (FBS), is a form of clinical neurobiology electrotherapy used to stimulate a neuron or neural network in the brain through the direct or indirect excitation of cell membranes using an electric current. See: en.wikipedia.org/wiki/Electrical_brain_stimulation; U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 7,753,836; 794,673; 8,545,378; 9,345,901; 9,610,456; 9,694,178; 20140330337; 20150112403; and 20150119689.

Motor skills can be affected by CNS stimulation.

See, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 5,343,871; 5,742,748; 6,057,846; 6,390,979; 6,644,976; 6,656,137; 7,063,535; 7,558,622; 7,618,381; 7,733,224; 7,829,562; 7,863,272; 8,016,597; 8,065,240; 8,069,125; 8,108,036; 8,126,542; 8,150,796; 8,195,593; 8,356,004; 8,449,471; 8,461,988; 8,525,673; 8,525,687; 8,531,291; 8,591,419; 8,606,592; 8,615,479; 8,680,991; 8,682,449; 8,706,518; 8,747,336; 8,750,971; 8,764,651; 8,784,109; 8,858,440; 8,862,236; 8,938,289; 8,962,042; 9,005,649; 9,064,036; 9,107,586; 9,125,788; 9,138,579; 9,149,599; 9,173,582; 9,204,796; 9,211,077; 9,265,458; 9,351,640; 9,358,361; 9,380,976; 9,403,038; 9,418,368; 9,468,541; 9,495,684; 9,545,515; 9,549,691; 9,560,967; 9,577,992; 9,590,986; 20030068605; 20040072133; 20050020483; 20050032827; 20050059689; 20050153268; 20060014753; 20060052386; 20060106326; 20060191543; 20060229164; 20070031798; 20070138886; 20070276270; 20080001735; 20080004904; 20080243005; 20080287821; 20080294019; 20090005654; 20090018407; 20090024050; 20090118593; 20090119154; 20090132275; 20090156907; 20090156955; 20090157323; 20090157481; 20090157482; 20090157625; 20090157660; 20090157751; 20090157813; 20090163777; 20090164131; 20090164132; 20090164302; 20090164401; 20090164403; 20090164458; 20090164503; 20090164549; 20090171164; 20090172540; 20090221928; 20090267758; 20090271011; 20090271120; 20090271347; 20090312595; 20090312668; 20090318773; 20090318779; 20090319002; 20100004762; 20100015583; 20100017001; 20100022820; 20100041958; 20100042578; 20100063368; 20100069724; 20100076249; 20100081860; 20100081861; 20100100036; 20100125561; 20100130811; 20100145219; 20100163027; 20100163035; 20100168525; 20100168602; 20100280332; 20110015209; 20110015469; 20110082154; 20110105859; 20110115624; 20110152284; 20110178441; 20110181422; 20110288119; 20120092156; 20120092157; 20120130300; 20120143104; 20120164613; 20120177716; 20120316793; 20120330109; 20130009783; 20130018592; 20130034837; 20130053656; 20130054215; 20130085678; 20130121984; 20130132029; 20130137717; 20130144537; 20130184728; 20130184997; 20130211291; 20130231574; 20130281890; 20130289385; 20130330428; 20140039571; 20140058528; 20140077946; 20140094720; 20140104059; 20140148479; 20140155430; 20140163425; 20140207224; 20140235965; 20140249429; 20150025410; 20150025422; 20150068069; 20150071907; 20150141773; 20150208982; 20150265583; 20150290419; 20150294067; 20150294085; 20150294086; 20150359467; 20150379878; 20160001096; 20160007904; 20160007915; 20160030749; 20160030750; 20160067492; 20160074657; 20160120437; 20160140834; 20160198968; 20160206671; 20160220821; 20160303402; 20160351069; 20160360965; 20170046971; 20170065638; 20170080320; 20170084187; 20170086672; 20170112947; 20170127727; 20170131293; 20170143966; 20170151436; 20170157343; and 20170193831.

Abraham, W. C., 2008. Metaplasticity: tuning synapses and networks for plasticity. Nature Reviews Neuroscience 9, 387.

Abrahamyan, A., Clifford, C. W., Arabzadeh, E., Harris, J. A., 2011. Improving visual sensitivity with subthreshold transcranial magnetic stimulation. J. Neuroscience 31, 3290-3294.

Adrian, E. D., 1928. The Basis of Sensation. W.W. Norton, New York

Amassian, V. E., Cracco, R. Q., Maccabee, P. J., Cracco, J. B., Rudell, A., Eberie, L., 1989. Suppression of visual perception by magnetic coil stimulation of human occipital cortex. Electroencephalography and Clin. Neurophysiology 74, 458462.

Amassian, V. E., Eberie, L., Maccabee, P. J., Cracco, R. Q., 1992. Modelling magnetic coil excitation of human cerebral cortex with a peripheral nerve immersed in a brain-shaped volume conductor the significance of fiber bending in excitation. Electroencephalography and Clin. Neurophysiology 85, 291-301.

Antal, A., Boros, K., Poreisz, C., Chaieb, L., Temey, D., Paulus, W., 2008. Comparatively weak after-effects of transcranial alternating current stimulation (tACS) on cortical excitability in humans. Brain Stimulation 1, 97-105.

Antal, A., Nitsche, M. A., Kruse, W., Kincses, T. Z., Hoffmann, K. P., Paulus, W., 2004. Direct current stimulation over V5 enhances visuomotor coordination by improving motion perception in humans. J. Cognitive Neuroscience 16, 521-527.

Ashbridge, E., Walsh, V., Cowey, A., 1997. Temporal aspects of visual search studied by transcranial magnetic stimulation. Neuropsychologia 35, 1121-1131.

Barker, A. T., Freeston, I. L., Jalinous, R., Jarratt, J. A., 1987. Magnetic stimulation of the human brain and peripheral nervous system: an introduction and the results of an initial clinical evaluation. Neurosurgery 20, 100-109.

Barker, A. T., Jalinous, R., Freeston, I. L., 1985. Non-invasive magnetic stimulation of human motor cortex Lancet 1, 1106-1107.

Bi, G., Poo, M., 2001. Synaptic modification by correlated activity: Hebb's postulate revisited. Annual Review of Neuroscience 24, 139-166.

Bialek, W., Rieke, F., 1992. Reliability and information transmission in spiking neurons. Trends in Neurosciences 15, 428-434.

Bienenstock, E. L., Cooper, L. N., Munro, P. W., 1982. Theory for the development of neuron selectivity orientation specificity and binocular interaction in visual cortex J. Neuroscience 2, 32-48.

Bindman, L. J., Lippold, O. C., Milne, A. R., 1979. Prolonged changes in excitability of pyramidal tract neurones in the cat a post-synaptic mechanism. J. Physiology 286, 457-477.

Bindman, L. J., Lippold, O. C., Redfeam, J. W., 1962. Long-lasting changes in the level of the electrical activity of the cerebral cortex produced by polarizing currents. Nature 196, 584-585.

Bindman, L. J., Lippold, O. C., Redfeam, J. W., 1964. The action of brief polarizing currents on the cerebral cortex of the rat (1) during current flow and (2) in the production of long-lasting after-effects. J. Physiology 172, 369-382.

Brignani, D., Ruzzdi, M., Mauri, P., Miniussi, C., 2013. Is transcranial alternating current stimulation effective in modulating brain oscillations? PLoS ONE 8, e56589. Buzsàki, G., 2006. Rhythms of the Brain. Oxford University Press, Oxford.

Canolty, R. T., Knight R. T., 2010. The functional role of cross-frequency coupling. Trends in Cognitive Sciences 14, 506-515.

Carandini, M., Ferster, D., 1997. A tonic hyperpolarization underlying contrast adaptation in cat visual cortex. Science 276, 949-952.

Cattaneo, L., Sandrini, M., Schwarzbach, J., 2010. State-dependent TMS reveals a hierarchical representation of observed acts in the temporal, parietal, and premotor cortices. Cerebral Cortex 20, 2252-2258.

Cattaneo, Z., Rota, F., Vecchi, T., Silvanto, J., 2008. Using state-dependency of trans-cranial magnetic stimulation (TMS) to investigate letter selectivity in the left posterior parietal cortex a comparison of TMS-priming and TMS-adaptation paradigms. Eur. J. Neuroscience 28, 1924-1929.

Chambers, C. D., Payne, J. M., Stokes, M. G., Mattingley, J. B., 2004. Fast and slow parietal pathways mediate spatial attention. Nature Neuroscience 7, 217-218.

Corthout E., Li, B., Walsh, V., Halleti, M., Cowey, A, 1999. Timing of activity in early visual cortex as revealed by transcranial magnetic stimulation. Neuroreport 10, 2631-2634.

Creutzfeldt O. D., Fromm, G. H., Kapp, H., 1962. Influence of transcortical d-c currents on cortical neuronal activity. Experimental Neurobgy 5, 436-452.

Deans, J. K., Powell, A. D., Jefferys, J. G., 2007. Sensitivity of coherent oscillations in rat hippocampus to AC electric fields. J. Physiology 583, 555-565.

Dockery, C. A., Hueckel-Weng, R., Birbaumer, N., Plewnia, C., 2009. Enhancement of planning ability by transcranial direct current stimulation. J. Neuroscience 29, 7271-7277.

Ermentrout G. B., Galan, R. F., Urban, N. N., 2008. Reliability, synchrony and noise. Trends in Neurosciences 31, 428-434.

Epstein, C. M., Rothwell, J. C., 2003. Therapeutic uses of rTMS. Cambridge University Press, Cambridge, pp. 246-263.

Faisal, A. A., Selen, L. P., Wolpert D. M., 2008. Noise in the nervous system. Nature Reviews Neuroscience 9, 292-303.

Ferbert A., Caramia, D., Priori, A., Bertolasi, L., Rothwell, J. C., 1992. Cortical projection to erector spinae muscles in man as assessed by focal transcranial magnetic stimulation. Electroencephalography and Clin. Neurophysiology 85, 382-387.

Fertonani, A., Pirulli, C., Miniussi, C., 2011. Random noise stimulation improves neuroplasticity in perceptual learning. J. Neuroscience 31, 15416-15423. Feurra, M., Galli, G., Rossi, S., 2012. Transcranial alternating current stimulation affects decision making. Frontiers in Systems Neuroscience 6, 39.

Guyonneau, R., Vanrullen, R., Thorpe, S. J., 2004. Temporal codes and sparse representations: a key to understanding rapid processing in the visual system. J. Physiology, Paris 98, 487-497.

Hallett M., 2000. Transcranial magnetic stimulation and the human brain. Nature 406, 147-150.

Harris, I. M., Miniussi, C., 2003. Parietal lobe contribution to mental rotation demonstrated with rTMS. J. Cognitive Neuroscience 15, 315-323.

Harris, J. A, Clifford, C. W., Miniussi, C., 2008. The functional effect of transcranial magnetic stimulation: signal suppression or neural noise generation. J. Cognitive Neuroscience 20, 734-740.

Hebb, D. O., 1949. The Organization of Behavior; A Neuropsychological Theory. Wiley, New York.

Hutcheon, B., Yarom, Y., 2000. Resonance, oscillation and the intrinsic frequency preferences of neurons. Trends in Neurosciences 23, 216-222.

Jacobson, L., Koslowsky, M., Lavidor, M., 2011. tDCS polarity effects in motor and cognitive domains: a meta-analytical review. Experimental Brain Research 216, 1-10.

Joundi, R. A., Jenkinson, N., Brittain, J. S., Aziz, T. Z., Brown, P., 2012. Driving oscillatory activity in the human cortex enhances motor performance. Current Biology 22, 403-407.

Kahn, I., Pascual-Leone, A., Theoret H., Fregni, F., Clark, D., Wagner, A. D., 2005. Transient disruption of ventrolateral prefrontal cortex during verbal encoding affects subsequent memory performance. J. Neurophysiology 94, 688-698.

Kanai, R., Chaieb, L., Antal, A., Walsh, V., Paulus, W., 2008. Frequency-dependent electrical stimulation of the visual cortex Current Biology 18, 1839-1843.

Kitajo, K., Doesburg, S. M., Yamanaka, K., Nozaki, D., Ward, L. M., Yamamoto, Y., 2007. Noise-induced large-scale phase synchronization of human-brain activity associated with behavioral stochastic resonance. EPL-Europhysics Letters, 80.

Kitajo, K., Nozaki, D., Ward, L. M., Yamamoto, Y., 2003. Behavioral stochastic resonance within the human brain. Physical Review Letters 90, 218-103.

Landi, D., Rossini, P. M., 2010. Cerebral restorative plasticity from normal aging to brain diseases: a never-ending story. Restorative Neurology and Neuroscience 28, 349-366.

Lang, N., Rothkegel, H., Reiber, H., Hasan, A., Sueske, E., Tergau, F., Ehrenreich, H., Wuttke, W., Paulus, W., 2011. Circadian modulation of GABA-mediated cortical inhibition. Cerebral Cortex 21, 2299-2306.

Laycock, R., Crewther, D. P., Fitzgerald, P. B., Crewther, S. G., 2007. Evidence for fast signals and later processing in human V1/V2 and V5/MT+. ATMS study of motion perception. J. Neurophysiology 98, 1253-1262.

Liebetanz, D., Nitsche, M. A., Tergau, F., Paulus, W., 2002. Pharmacological approach to the mechanisms of transcranial DC-stimulation-induced after-effects of human motor cortex excitability. Brain 125, 2238-2247.

Longtin, A., 1997. Autonomous stochastic resonance in bursting neurons. Physical Review E 55, 868-876.

Manenti, R., Cappa, S. F., Rossini, P. M., Miniussi, C., 2008. The role of the prefrontal cortex in sentence comprehension: an rTMS study. Cortex 44, 337-344.

Marzi, C. A., Miniussi, C., Maravita, A., Bertolasi, L., Zanette, G., Rothwell, J. C., Sanes, J. N., 1998. Transcranial magnetic stimulation selectively impairs interhemispheric transfer of visuo-motor information in humans. Experimental Brain Research 118, 435-438.

Masquelier, T., Thorpe, S. J., 2007. Unsupervised learning of visual features through spike timing dependent plasticity. PLOS Computational Biology 3, e31.

Miniussi, C., Brignani, D., Pellicciari, M. C., 2012a. Combining transcranial electrical stimulation with electroencephalography a multimodal approach. Clin. EEG and Neuroscience 43, 184-191.

Miniussi, C., Paulus, W., Rossini, P. M., 2012b. Transcranial Brain Stimulation. CRC Press, Boca Raton, Fla.

Miniussi, C., Ruzzoli, M., Walsh, V., 2010. The mechanism of transcranial magnetic stimulation in cognition. Cortex 46, 128-130.

Moliadze, V., Zhao, Y., Eysel, U., Funke, K., 2003. Effect of transcranial magnetic stimulation on single-unit activity in the cat primary visual cortex. J. Physiology 553, 665-679.

Moss, F., Ward, L. M., Sannita, W. G., 2004. Stochastic resonance and sensory information processing: a tutorial and review of application. Clin. Neurophysiology 115, 267-281.

Mottaghy, F. M., Gangitano, M., Krause, B. J., Pascual-Leone, A., 2003. Chronometry of parietal and prefrontal activations in verbal working memory revealed by transcranial magnetic stimulation. Neuroimage 18, 565-575.

Nachmias, J., Sansbury, R. V., 1974. Grating contrast discrimination may be better than detection. Vision Research 14, 1039-1042.

Nitsche, M. A., Cohen, L. G., Wassermann, E. M., Priori, A., Lang, N., Antal, A., Paulus, W., Hummel, F., Boggio, P. S., Fregni, F., Pascual-Leone, A., 2008. Transcranial direct current stimulation: state of the art 2008. Brain Stimulation 1, 206-223.

Nitsche, M. A., Liebetanz, D., Lang, N., Antal, A., Tergau, F., Paulus, W., 2003 a Safety criteria for transcranial direct current stimulation (DCS) in humans. Clin. Neurophysiology 114, 2220-2222, author reply 2222-2223.

Nitsche, M. A, Niehaus, L., Hoffmann, K. T., Hengst S., Liebetanz, D., Paulus, W., Meyer, B. U., 2004. MRI study of human brain exposed to weak direct current stimulation of the frontal cortex. Clin. Neurophysiology 115, 2419-2423.

Nitsche, M. A, Nitsche, M. S., Klein, C. C., Tergau, F., Rothwell, J. C., Paulus, W., 2003b. Level of action of cathodal DC polarisation induced inhibition of the human motor cortex. Clin. Neurophysiology 114, 600-604.

Nitsche, M. A, Paulus, W., 2000. Excitability changes induced in the human motor cortex by weak transcranial direct current stimulation. J. Physiology 527 (Pt 3), 633-639.

Nitsche, M. A., Paulus, W., 2011. Transcranial direct current stimulation—update 2011. Restorative Neurology and Neuroscience 29, 463-492.

Nitsche, M. A., Seeber, A., Frommann, K., Klein, C. C., Rochford, C., Nitsche, M. S., Fricke, K., Liebetanz, D., Lang, N., Antal, A., Paulus, W., Tengau, F., 2005. Modulating parameters of excitability during and after transcranial direct current stimulation of the human motor cortex J. Physiology 568, 291-303.

Pascual-Leone, A., Walsh, V., Rothwell, J., 2000. Transcranial magnetic stimulation in cognitive neuroscience-virtual lesion, chronometry, and functional connectivity. Current Opinion in Neurobiology 10, 232-237.

Pasley, B. N., Allen, E. A., Freeman, R. D., 2009. State-dependent variability of neuronal responses to transcranial magnetic stimulation of the visual cortex Neuron 62, 291-303.

Paulus, W., 2011. Transcranial electrical stimulation (tES-tDCS; tRNS, tACS) methods. Neuropsychological Rehabilitation 21, 602-617.

Plewnia, C., Rilk, A. J., Soekadar, S. R, Arfeller, C., Huber, H. S., Sauseng, P., Hummel, F., Gerloff, C., 2008. Enhancement of long-range EEG coherence by synchronous bifocal transcranial magnetic stimulation. European J. Neuroscience 27, 1577-1583.

Pogosyan, A., Gaynor, L. D., Eusebio, A., Brown, P., 2009. Boosting cortical activity at Beta-band frequencies slows movement in humans. Current Biology 19, 1637-1641.

Priori, A., Berandelli, A., Rona, S., Accomero, N., Manfredi, M., 1998. Polarization of the human motor cortex through the scalp. Neuroreport 9, 2257-2260.

Radman, T., Datta, A., Peterchev, A. V., 2007. In vitro modulation of endogenous rhythms by AC electric fields: syncing with clinical brain stimulation. J. Physiology 584, 369-370.

Rahnev, D. A., Maniscalco, B., Luber, B., Lau, H., Lisanby, S. H., 2012. Direct injection of noise to the visual cortex decreases accuracy but increases decision confidence. J. Neurophysiology 107, 1556-1563.

Reato, D., Rahman, A., Bikson, M., Parra, L. C., 2010. Low-intensity electrical stimulation affects network dynamics by modulating population rate and spike timing. J. Neuroscience 30, 15067-15079.

Ridding, M. C., Ziemann, U., 2010. Determinants of the induction of cortical plasticity by non-invasive brain stimulation in healthy subjects. J. Physiology 588, 2291-2304.

Rosanova, M., Casali, A., Bellina, V., Resta, F., Mariotti, M., Massimini, M., 2009. Natural frequencies of human corticothalamic circuits. J. Neuroscience 29, 7679-7685.

Rossi, S., Hallett, M., Rossini, P. M., Pascual-Leone, A., Safety of TMS Consensus Group, 2009. Safety, ethical considerations, and application guidelines for the use of transcranial magnetic stimulation in clinical practice and research. Clin. Neurophysiology 120, 2008-2039.

Roth, B. J., 1994. Mechanisms for electrical stimulation of excitable tissue. Critical Reviews in Biomedical Engineering 22, 253-305.

Rothwell, J. C., Day, B. L., Thompson, P. D., Dick, J. P., Marsden, C. D., 1987. Some experiences of techniques for stimulation of the human cerebral motor cortex through the scalp. Neurosurgery 20, 156-163.

Ruohonen, J., 2003. Background physics for magnetic stimulation. Supplements to Clin. Neurophysiology 56, 3-12.

Ruzzoli, M., Abrahamyan, A., Clifford, C. W., Marzi, C. A., Miniussi, C., Harris, J. A., 2011. The effect of TMS on visual motion sensitivity: an increase in neural noise or a decrease in signal strength. J. Neurophysiology 106, 138-143.

Ruzzoli, M., Marzi, C. A., Miniussi, C., 2010. The neural mechanisms of the effects of transcranial magnetic stimulation on perception. J. Neurophysiology 103, 2982-2989.

Sack, A. T., Linden, D. E., 2003. Combining transcranial magnetic stimulation and functional imaging in cognitive brain research: possibilities and limitations. Brain Research: Brain Research Reviews 43, 41-56.

Sandrini, M., Umilta, C., Rusconi, E., 2011. The use of transcranial magnetic stimulation in cognitive neuroscience: a new synthesis of methodological issues. Neuroscience and Biobehavioral Reviews 35, 516-536.

Schutter, D. J., Hortensius, R., 2010. Retinal origin of phosphenes to transcranial alternating current stimulation. Clin. Neurophysiology 121, 1080-1084.

Schwarzkopf, D. S., Silvanfo, J., Rees, G., 2011. Stochastic resonance effects reveal the neural mechanisms of transcranial magnetic stimulation. J. Neuro-science 31, 3143-3147.

Schwiedrzik, C. M., 2009. Retina or visual cortex? The site of phosphene induction by transcranial alternating current stimulation. Frontiers in Integrative Neuro-science 3, 6.

Sclar, G., Lennie, P., DePriest, D. D., 1989. Contrast adaptation in striate cortex of macaque. Vision Research 29, 747-755.

Seyal, M., Masuoka, L. K., Browne, J. K., 1992. Suppression of cutaneous perception by magnetic pulse stimulation of the human brain. Electroencephalography and Clin. Neurophysiology 85, 397-401.

Siebner, H. R., Lang, N., Rizzo, V., Nitsche, M. A., Paulus, W., Lemon, R. N., Rothwell, J. C., 2004. Preconditioning of low-frequency repetitive transcranial magnetic stimulation with transcranial direct current stimulation: evidence for homeostatic plasticity in the human motor cortex. The J. Neuroscience 24, 3379-3385.

Silvanto, J., Muggleton, N., Walsh, V., 2008. State-dependency in brain stimulation studies of perception and cognition. Trends in Cognitive Sciences 12, 447-454.

Silvanto, J., Muggleton, N. G., Cowey, A., Walsh, V., 2007. Neural adaptation reveals state-dependent effects of transcranial magnetic stimulation. Eur. J. Neuroscience 25, 1874-1881.

Solomon, J. A, 2009. The history of dipper functions. Attention, Perception, and Psychophysics 71, 435-443.

Stein, R. B., Gossen, E. R., Jones, K. E., 2005. Neuronal variability noise or part of the signal? Nature Reviews Neuroscience 6, 389-397.

Temey, D., Chaieb, L, Moliadze, V., Antal, A., Paulus, W., 2008. Increasing human brain excitability by transcranial high-frequency random noise stimulation. J. Neuroscience 28, 14147-14155.

Thut, G., Miniussi, C., 2009. New insights into rhythmic brain activity from TMS-EEG studies. Trends in Cognitive Sciences 13, 182-189.

Thut, G., Miniussi, C., Gross, J., 2012. The functional importance of rhythmic activity in the brain. Current Biology 22, R658-R663.

Thut G., Schyns, P. G., Gross, J., 2011a. Entrapment of perceptually relevant brain oscillations by non-invasive rhythmic stimulation of the human brain. Front Psychology 2, 170.

Thut G., Veniero, D., Romei, V., Miniussi, C., Schyns, P., Gross, J., 2011b. Rhythmic TMS causes local entrainment of natural oscillatory signatures. Current Biology 21, 1176-1185.

Vallar, G., Bolognini, N., 2011. Behavioural facilitation following brain stimulation: implications for neurorehabilitation. Neuropsychological Rehabilitation 21, 618-649.

Varela, F., Lachaux, J. P., Rodriguez, E., Martinerie, J., 2001. The brainweb: phase synchronization and large-scale integration. Nature Reviews Neuroscience 2, 229-239.

Veniero, D., Brignani, D., Thut G., Miniussi, C., 2011. Alpha-generation as basic response-signature to transcranial magnetic stimulation (TMS) targeting the human resting motor cortex: a TMS/EEG co-registration study. Psychophysiology 48, 1381-1389.

Walsh, V., Cowey, A., 2000. Transcranial magnetic stimulation and cognitive neuroscience. Nature Reviews Neuroscience 1, 73-79.

Walsh, V., Ellison, A., Battelli, L., Cowey, A, 1998. Task-specific impairments and enhancements induced by magnetic stimulation of human visual area V5. Proceedings: Biological Sciences 265, 537-543.

Walsh, V., Pascual-Leone, A., 2003. Transcranial Magnetic Stimulation: A Neurochronometrics of Mind. MIT Press, Cambridge, Mass.

Walsh, V., Rushworth, M., 1999. A primer of magnetic stimulation as a tool for neuropsychology. Neuropsychologia 37, 125-135.

Ward, L. M., Doesburg, S. M., Kitajo, K., MacLean, S. E., Roggeveen, A. B., 2006. Neural synchrony in stochastic resonance, attention, and consciousness. Canadian J. Experimental Psychology 60, 319-326.

Wassermann, E. M., Epstein, C., Ziemann, U., Walsh, V., Paus, T., Lisanby, S., 2008.

Handbook of Transcranial Stimulation. Oxford University Press, Oxford, UK.

Waterston, M. L., Pack C. C., 2010. Improved discrimination of visual stimuli following repetitive transcranial magnetic stimulation. PLoS ONE 5, e10354.

Wu, S., Amari, S., Nakahara, H., 2002. Population coding and decoding in a neural field: a computational study. Neural Computation 14, 999-1026.

Zaehle, T., Rach, S., Herrmann, C. S., 2010. Transcranial alternating current stimulation enhances individual alpha activity in human EEG. PLoS ONE 5, e13766.

Michael A Nitsche, and Armin Kibele. “Noninvasive brain stimulation and neural entrapment enhance athletic performance—a review.” J. Cognitive Enhancement 1.1 (2017): 73-79, discusses that non-invasive brain stimulation (NIBS) bypasses the correlative approaches of other imaging techniques, making it possible to establish a causal relationship between cognitive processes and the functioning of specific brain areas. NIBS can provide information about where a particular process occurs. NIBS offers the opportunity to study brain mechanisms beyond process localization, providing information about when activity in a given brain region is involved in a cognitive process, and even how it is involved. When using NIBS to explore cognitive processes, it is important to understand not only how NIBS functions but also the functioning of the neural structures themselves. Non-invasive brain stimulation (NIBS) methods, which include transcranial magnetic stimulation (TMS) and transcranial electric stimulation (tES), are used in cognitive neuroscience to induce transient changes in brain activity and thereby alter the behavior of the subject. The application of NIBS aims at establishing the role of a given cortical area in an ongoing specific motor, perceptual or cognitive process (Hallett, 2000; Walsh and Cowey, 2000). Physically, NIBS techniques affect neuronal states through different mechanisms. In TMS, a solenoid (coil) is used to deliver a strong and transient magnetic field, or “pulse,” to induce a transitory electric current at the cortical surface beneath the coil. (US 2004078056) The pulse causes the rapid and above-threshold depolarization of cell membranes affected by the current (Barker et al., 1985, 1987), followed by the transsynaptic depolarization or hyperpolarization of interconnected neurons. Therefore, TMS induces a current that elicits action potentials in neurons. A complex set of coils can deliver a complex 3D excitation field. By contrast in tES techniques, the stimulation involves the application of weak electrical currents directly to the scalp through a pair of electrodes (Nitsche and Paulus, 2000; Priori et al., 1998). As a result tES induces a subthreshold polarization of cortical neurons that is too weak to generate an action potential. However, by changing the intrinsic neuronal excitability, tES can induce changes in the resting membrane potential and the postsynaptic activity of cortical neurons. This, in turn, can alter the spontaneous firing rate of neurons and modulate their response to afferent signals (Bindman et al., 1962, 1964, 1979; Creutzfeldt et al., 1962), leading to changes in synaptic efficacy. The typical application of NIBS involves different types of protocols: TMS can be delivered as a single pulse (spTMS) at a precise time, as pairs of pulses separated by a variable interval, or as a series of stimuli in conventional or patterned protocols of repetitive TMS (rTMS) (for a complete classification see Rossi et al., 2009). In tES, different protocols are established by the electrical current used and by its polarity, which can be direct (anodal or cathodal transcranial direct current stimulation: tDCS), high-definition transcranial direct current stimulation (HD-tDCS), oscillating transcranial direct current stimulation (osc-tDCS), alternating at a fix frequency (transcranial alternating current stimulation: tACS) transcranial pulsed current stimulation (tPCS) (electrosleep), or at random frequencies (transcranial random noise stimulation: tRNS) (Nitsche et al., 2008; Paulus, 2011).

NIBS also includes brain entrainment using light stimulation and sound stimulation. The latter can be binaural beats (BB) or isochronic tones.

In general, the final effects of NIBS on the central nervous system depend on a lengthy list of parameters (e.g., frequency, temporal characteristics, intensity, geometric configuration of the coil/electrode, i.e., “montage,” current direction), when it is delivered before (off-line) or during (on-line) the task as part of the experimental procedure (e.g., Jacobson et al., 2011; Nitsche and Paulus, 2011; Sandrini et al., 2011). In addition, these factors interact with several variables related to the brain anatomy and morphology (e.g., brain size, properties of the brain tissue and its location, Radman et al., 2007), as well as physiological (e.g., gender and age, Landi and Rossini, 2010; Lang et al., 2011; Ridding and Ziemann, 2010) and cognitive (e.g., Miniussi et al., 2010; Silvanto et al., 2008; Walsh et al., 1998) states of the stimulated area/subject.

Transcranial Direct Current Stimulation (tDCS) Cranial electrotherapy stimulation (CES) is a form of non-invasive brain stimulation that applies a small, pulsed electric current across a person's head to treat a variety of conditions such as anxiety, depression and insomnia. See, en.wikipedia.org/wiki/Cranial_electrotherapy_stimulation. Transcranial direct current stimulation (tDCS, HD-tDCS, osc-tDCS, tPCS) is a form of neurostimulation that uses constant, low current delivered to the brain area of interest via electrodes on the scalp. It was originally developed to help patients with brain injuries or psychiatric conditions like major depressive disorder. tDCS appears to have some potential for treating depression. See, en.wikipedia.org/wiki/Transcranial_direct-current_stimulation.

The hypotheses concerning the application of tDCS in cognition are very similar to those of TMS, with the exception that tDCS was never considered a virtual lesion method. tDCS can increase a decrease cortical excitability in the stimulated brain regions and facilitate or inhibit behavior accordingly. TES does not induce action potentials but instead modulates the neuronal response threshold so that it can be defined as subthreshold stimulation.

tDCS is being studied for acceleration of learning. The mild electrical shock (usually, a 2-milliamp current) is used to depolarize the neuronal membranes, making the cells more excitable and responsive to inputs. Weisend, Experimental Brain Research, vol 213, p 9 (DARPA) showed that tDCS accelerates the formation of new neural pathways during the time that someone practices a skill. tDCS appears to bring about the flow state. The movements of the subjects become more automatic; they report calm, focused concentration, and their performance improves immediately. (See Adee, Sally, “Zap your brain into the zone: Fast track to pure locus”, New Scientist, No. 2850, Feb. 1, 2012, www.newscientist.com/article/mg21328501-600-zap-your-brain-into-the-zone-fast-track-to-pure-focus/).

U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 7,856,264; 8,706,241; 8,725,669; 9,037,224; 9,042,201; 9,095,266; 9,248,286; 9,349,178; 9,629,568; 9,693,725; 9,713,433; 20040195512; 20070179534; 20110092882; 20110311021; 20120165696; 20140142654; 20140200432; 20140211593; 20140316243; 20140347265; 20150099946; 20150174418; 20150257700; 20150327813; 20150343242; 20150351655; 20160000354; 20160038049; 20160113569; 20160144175; 20160148371; 20160148372; 20160180042; 20160213276; 20160228702; and 20160235323.

Reinhart, Robert M G. “Disruption and rescue of interareal theta phase coupling and adaptive behavior.” Proceedings of the National Academy of Sciences (2017): provide evidence for a causal relation between interareal theta phase synchronization in frontal cortex and multiple components of adaptive human behavior. Reinhart's results support the idea that the precise timing of rhythmic population activity spatially distributed in frontal cortex conveys information to direct behavior. Given prior work showing that phase synchronization can change spike time-dependent plasticity, together with Reinhart's findings showing stimulation effects on neural activity and behavior can outlast a 20-min period of electrical stimulation, it is reasonable to suppose that the externally modulated interareal coupling changed behavior by causing neuroplastic modifications in functional connectivity. Reinhart suggests that we may be able to noninvasively intervene in the temporal coupling of distant rhythmic activity in the human brain to optimize (or impede) the postsynaptic effect of spikes from one area on the other, improving (or impairing) the cross-area communication necessary for cognitive action control and learning. Moreover, these neuroplastic alterations in functional connectivity were induced with a 0° phase, suggesting that inducing synchronization does not require a meticulous accounting of the communication delay between regions such as medial frontal cortex (MFC) and lateral prefrontal cortex (lPFC) to effectively modify behavior and learning. This conforms to work showing that despite long axonal conduction delays between distant brain areas, theta phase synchronizations at 0° phase lag can occur between these regions and underlie meaningful functions of cognition and action. It is also possible that a third subcortical or posterior region with a nonzero time lag interacted with these two frontal areas to drive changes in goal-directed behavior.

Alexander W H & Brown J W (2011) Medial prefrontal cortex as an action-outcome predictor. Nature Neuroscience 14(10):1338-1344.

Alexander W H & Brown J W (2015) Hierarchical error representation: A computational model of anterior cingulate and dorsolateral prefrontal cortex Neural Computation 27:2354-2410.

Anguera J A et al. (2013) Video game training enhances cognitive control in older adults. Nature 501:97-101.

Aron A R, Fletcher P C, Bullmore E T, Sahakian B J, Robbins T W (2003) Stop-signal inhibition disrupted by damage to right inferior frontal gyrus in humans. Nat Neurosci 6:115-116.

Au J, et al. (2015) Improving fluid intelligence with training on working memory a meta-analysis. Psychonomic Bulletin & Review 22:366-377.

Bellman R, Kalaba R (1959) A mathematical theory of adaptive control processes. Proc Natl Acad Sci USA 45:1288-1290.

Bibbig A, Traub R D, Whittington M A (2002) Long-range synchronization of gamma and beta oscillations and the plasticity of excitatory and inhibitory synapses: A network model. J Neurophysiol 88:1634-1654.

Botvinick M M (2012) Hierarchical reinforcement learning and decision making. Current Opinion in Neurobiology 22(6):956-962.

Botvinick M M, Braver T S, Barch D M, Carter C S, & Cohen J D (2001) Conflict monitoring and cognitive control. Psychological Review 108(3):624-652.

Bryck R L & Fisher P A (2012) Training the brain: practical applications of neural plasticity from the intersection of cognitive neuroscience, developmental psychology, and prevention science. American Psychologist 67:87-100.

Cavanagh J F, Cohen M X, & Allen J J (2009) Prelude to and resolution of an error: EEG phase synchrony reveals cognitive control dynamics during action monitoring. Journal of Neuroscience 29(1):98-105.

Cavanagh J F, Frank M J (2014) Frontal theta as a mechanism for cognitive control. Trends Cogn Sci 18:414-421.

Christie G J, Tata M S (2009) Right frontal cortex generates reward-related theta-band oscillatory activity. Neuroimage 48:415-422.

Cohen M X, Wilmes K, Vijver Iv (2011) Cortical electrophysiological network dynamics of feedback learning. Trends Cogn Sci 15:558-566.

Corbett A, et al. (2015) The effect of an online cognitive training package in healthy older adults: An online randomized controlled trial. J Am Med Dir Assoc 16:990-997.

Dale A M & Sereno M I (1993) Improved localization of cortical activity by combining EEG and MEG with MRI cortical surface reconstruction: A linear approach. Journal of Cognitive Neuroscience 5:162-176.

Dalley J W, Robbins T W (2017) Fractionating impulsivity: Neuropsychiatry implications. Nat Rev Neurosci 18:158-171.

Delome A & Makeig S (2004) EEGLAB: An open source toolbox for analysis of single-trial EEG dynamics including independent component analysis. Journal of Neuroscience Methods 134(1):9-21.

Diamond A & Lee K (2011) Interventions and programs demonstrated to aid executive function development in children 4-12 years of age. Science 333:959964.

Engel A K, Fries P, Singer W (2001) Dynamic predictions: Oscillations and synchrony in top-down processing. Nat Rev Neurosci 2:704-716.

Fairclough S H & Houston K (2004) A metabolic measure of mental effort Biological Psychology 66:177-190.

Fell J, Axmacher N (2011) The role of phase synchronization in memory processes. Nat Rev Neurosci 12:105-118.

Fitzgerald K D, et al. (2005) Error-related hyperactivity of the anterior cingulate cortex in obsessive-compulsive disorder. Biol Psychiatry 57:287-294.

Foti D, Weinberg A Dien J, Hajcak G (2011) Event-related potential activity in the basal ganglia differentiates rewards from nonrewards: Temporospatial principal components analysis and source localization of the feedback negativity. Hum Brain Mapp 32:2207-2216.

Fuchs M, Drenckhahn R, Wischmann H A & Wagner M (1998) An improved boundary element method for realistic volume-conductor modeling. IEEE Trans Biomed Eng 45(8):980-997.

Gailliot M T & Baumeister R F (2007) The physiology of willpower linking blood glucose to self-control. Personality and Social Psychology Review 11 (4):303-327.

Gandiga P, Hummel F, & Cohen L (2006) Transcranial DC stimulation (tDCS): A tool for double-blind sham-controlled clinical studies in brain stimulation. Clinical Neurophysiology 117(4):845-850.

Gregoriou G G, Gotts S J, Zhou H, Desimone R (2009) High-frequency, long-range coupling between prefrontal and visual cortex during attention. Science 324:1207-1210.

Hillman C H, Erickson K I, & Kramer A F (2008) Be smart, exercise your heart exercise effects on brain and cognition. Nature Reviews Neuroscience 9(1):5865.

Holroyd C B & Yeung N (2012) Motivation of extended behaviors by anterior cingulate cortex. Trends in Cognitive Sciences 16:122-128.

Inzlicht M, Schmeichel B J, & Macrae C N (2014) Why self-control seems (but may not be) limited. Trends in Cognitive Sciences 18(3):127-133.

Jennings J R & Wood C C (1976) The e-adjustment procedure for repeated measures analyses of variance. Psychophysiology 13:277-278.

Kanai R, Chaieb L, Antal A Walsh V, & Paulus W (2008) Frequency-dependent electrical stimulation of the visual cortex. Current Biology 18(23):1839-1843.

Kayser J & Tenke C E (2006) Principal components analysis of Laplacian waveforms as a generic method for identifying estimates: II. Adequacy of low-density estimates. Clinical Neurophysiology 117: 369-380.

Kramer A F & Erickson K I (2007) Capitalizing on cortical plasticity: influence of physical activity on cognition and brain function. Trends in Cognitive Sciences 11:342-348.

Kurland J, Baldwin K, Tauer C (2010) Treatment-induced neuroplasticity following intensive naming therapy in a case of chronic Wernicke's aphasia. Aphasiology 24:737-751.

Lachaux J P, Rodriguez E, Martinerie J, & Varela F J (1999) Measuring phase synchrony in brain signals. Human Brain Mapping 8:194-208.

Lennie P (2003) The cost of cortical computation. Current Biology 13:493-497.

Luft C D B, Nolte G, & Bhattacharya J (2013) High-learners present larger midfrontal theta power and connectivity in response to incorrect performance feedback. Journal of Neuroscience 33(5):2029-2038.

Luft C D B, Nolte G, Bhattacharya J (2013) High-learners present larger mid-frontal theta power and connectivity in response to incorrect performance feedback. J Neurosci 33:2029-2038.

Marco-Pallares J, et al. (2008) Human oscillatory activity associated to reward processing in a gambling task. Neuropsychologia 46:241-248.

Marcora S M, Staiano W, & Manning V (2009) Mental fatigue impairs physical performance in humans. Journal of Applied Physiology 106:857-864.

Miltner W H R, Braun C H, & Coles M G H (1997) Event-related brain potentials following incorrect feedback in a time-estimation task: evidence for a “generic” neural system for error detection. Journal of Cognitive Neuroscience 9:788-798.

Noury N, Hipp J F, Siegel M (2016) Physiological processes non-linearly affect electrophysiological recordings during transcranial electric stimulation. Neuroimage 140:99-109.

Oostenveld R, Fries P, Maris E, & Schoffelen J M (2011) FieldTrip: Open source software for advanced analysis of MEG, EEG, and invasive electrophysiological data. Computational Intelligence and Neuroscience 2011:1-9.

Owen A M, et al. (2010) Putting brain training to the test Nature 465:775-778.

Pascual-Marqui R D (2002) Standardized low-resolution brain electromagnetic tomography (sLORETA): technical details. Methods & Findings in Experimental & Clinical Pharmacology 24:5-12.

Paulus W (2010) On the difficulties of separating retinal from cortical origins of phosphenes when using transcranial alternating current stimulation (tACS). Clinical Neurophysiology 121:987-991.

Poreisz C, Boros K, Antal A, & Paulus W (2007) Safety aspects of transcranial direct current stimulation concerning healthy subjects and patients. Brain Research Bulletin 72(4-6):208-214.

Raichle M E & Mintun M A (2006) Brain work and brain imaging. Annual Review of Neuroscience 29:449-476.

Reinhart R M G & Woodman G F (2014) Causal control of medial-frontal cortex governs electrophysiological and behavioral indices of performance monitoring and learning. Journal of Neuroscience 34(12):4214-4227.

Reinhart R M G & Woodman G F (2015) Enhancing long-term memory with stimulation tunes visual attention in one trial. Proceedings of the National Academy of Sciences of the USA 112(2):625-630.

Reinhart R M G, Cosman J D, Fukuda K, & Woodman G F (2017) Using transcranial direct-current stimulation (tDCS) to understand cognitive processing. Attention, Perception & Psychophysics 79(1):3-23.

Reinhart R M G, Woodman G F (2014) Oscillatory coupling reveals the dynamic reorganization of large-scale neural networks as cognitive demands change. J Cogn Neurosci 26:175-188.

Reinhart R M G, Xiao W, McQenahan L, & Woodman G F (2016) Electrical stimulation of visual cortex can immediately improve spatial vision. Current Biology 25(14):1867-1872.

Reinhart R M G, Zhu J, Park S, & Woodman G F (2015) Medial-frontal stimulation enhances learning in schizophrenia by restoring prediction-error signaling. Journal of Neuroscience 35(35):12232-12240.

Reinhart R M G, Zhu J, Park S, & Woodman G F (2015) Synchronizing theta oscillations with direct-current stimulation strengthens adaptive control in the human brain. Proceedings of the National Academy of Sciences of the USA 112(30):9448-9453.

Ridderinkhof K R, Ullsperger M, Crone E A, & Nieuwenhuis S (2004) The role of the medial frontal cortex in cognitive control. Science 306:443-447.

Salinas E, Sqnowski T J (2001) Correlated neuronal activity and the flow of neural information. Nat Rev Neurosci 2:539-550.

Schnitzler A, Gross J (2005) Normal and pathological oscillatory communication in the brain. Nat Rev Neurosci 6: 285-296.

Schutter D J & Hortensius R (2010) Retinal origin of phosphenes to transcranial alternating current stimulation. Clinical Neurophysiology 121 (7):1080-1084.

Shallice T, Gazzaniga M S (2004) The fractionation of supervisory control. The Cognitive Neuroscience (MIT Press, Cambridge, Mass.), pp 943-956.

Shenhav A, Botvinick M M, & Cohen J D (2013) The expected value of control: An integrative theory of anterior cingulate cortex function. Neuron 79:217-240.

Shenhav A, Cohen J D, & Botvinick M M (2016) Dorsal anterior cingulate cortex and the value of control. Nature Neuroscience 19:1286-1291.

Siegel M, Donner T H, Engel A K (2012) Spectral fingerprints of large-scale neuronal interactions. Nat Rev Neurosci 13:121-134.

Srinivasan R, Winter W R, Ding J, & Nunez P L (2007) EEG and MEG coherence: measures of functional connectivity at distinct spatial scales of neocortical dynamics. Journal of Neuroscience Methods 166(1):41-52.

Tang Y, et al. (2010) Short term mental training induces white-matter changes in the anterior cingulate. Proceedings of the National Academy of Sciences 107:16649-16652.

Tang Y Y, et al. (2009) Central and autonomic nervous system interaction is altered by short term meditation. Proceedings of the National Academy of Sciences 106:8865-8870.

Thrane G, Friborg O, Anke A, Indredavik B (2014) A meta-analysis of constraint-induced movement therapy after stroke. J Rehabil Med 46:833-842.

Uhlhaas P J, Singer W (2006) Neural synchrony in brain disorders: Relevance for cognitive dysfunctions and pathophysiology. Neuron 52:155-168.

Uhlhaas P J, Singer W (2010) Abnormal neural oscillations and synchrony in schizophrenia Nat Rev Neurosci 11:100-113.

van de Vijver I, Ridderinkhof K R, & Cohen M X (2011) Frontal oscillatory dynamics predict feedback learning and action adjustment Journal of Cognitive Neuroscience 23:4106-4121.

van Driel J, Ridderinkhof K R, & Cohen M X (2012) Not all errors are alike: Theta and alpha EEG dynamics relate to differences in error-processing dynamics. Journal of Neuroscience 32(47):16795-16806.

van Meel C S, Heslenfeld D J, Oosterlaan J, Sergeant J A (2007) Adaptive control deficits in attention-deficit/hyperactivity disorder (ADHD): The role of error processing. Psychiatry Res 151:211-220.

Varela F, Lachaux J P, Rodriguez E, Martinerie J (2001) The brainweb: Phase synchronization and large-scale integration. Nat Rev Neurosci 2: 229-239.

Velligan D I, Ritch J L, Sui D, DiCocco M, Huntzinger C D (2002) Frontal systems behavior scale in schizophrenia: Relationships with psychiatric symptomatology, cognition and adaptive function. Psychiatry Res 113:227-236.

Vicente R, Gollo L L, Mirasso C R, Fischer I, Pipa G (2008) Dynamical relaying can yield zero time lag neuronal synchrony despite long conduction delays. Proc Natl Acad Sci USA 105:17157-17162.

Wagner M, Fuchs M, & Kastner J (2007) SWARM: sLORETA-weighted accurate minimum norm inverse solutions. International Congress Series 1300: 185-188.

Wang X J (2010) Neurophysiologies and computational principles of cortical rhythms in cognition. Physiol Rev 90:1195-1268.

Wolpert D M, Diedrichsen J, & Flanagan J R (2011) Principles of sensorimotor learning. Nature Reviews Neuroscience 12: 739-751.

Xue S, Tang Y Y, Tang R, & Posner M I (2014) Short-term meditation induces changes in brain resting EEG theta networks. Brain & Cognition 87:1-6

Zatorre R J, Fields R D, & Johansen-Berg H (2012) Plasticity in gray and white: neuroimaging changes in brain structure during learning. Nature Neuroscience 15(4):528-536. See, Daniel Stevenson. “Intro to Transcranial Direct Current Stimulation (tDCS)” (Mar. 26, 2017) (www.slideshare.net/DanielStevenson27/intro-to-transcranial-direct stimulation-tdcs).

High-Definition-tDCS High-Definition transcranial Direct Current Stimulation (HD-tDCS) was invented by Dr. Marom Bikson's group at The City College of New York with the introduction of the 4×1 HD-tDCS montage. The 4×1 HD-tDCS montage allows precise targeting of cortical structures. The region of current flow is circumscribed by the area of the 4× ring, such that decreasing ring radius increases locality. 4×1 HD-tDCS allows for unifocal stimulation, meaning the polarity of the center 1× electrode will determine the direction of neuromodulation under the ring. This is in contrast to conventional tDCS where the need for one anode and one cathode always produces bidirectional modulation (even when an extra-cephalic electrode is used). 4×1 HD-tDCS thus provides the ability not only to select a cortical brain region to target but to modulate the excitability of that brain region with a designed polarity without having to consider return counter-electrode flow.

Osc-tDCS Oscillating transcranial direct current stimulation (osc-tDCS) is a tDCS wherein the amplitude of the current is modulated with a sinusoid waveform of a certain frequency. Osc-tDCS modulates the spontaneous brain activity in a frequency-specific manner. Osc-tDCS mainly affects brain oscillatory activity. Anodal oscillatory stimulation at 0.75 Hz (slow osc-tDCS) in frontal areas during sleep stage 2 of a diurnal nap or during nocturnal sleep can induce a frequency-specific enhancement of Slow-Wave Activity (SWA 0.5-4 Hz) during sleep. The enhancement in normal subjects of SWA induced by osc-tDCS at 0.75 Hz during sleep significantly improves performance in a memory task after sleep. See Bergmann T O, Groppa S, Seeger M, Mölle M, Marshall L, Siebner H R. “Acute changes in motor cortical excitability during slow oscillatory and constant anodal transcranial direct current stimulation.” J Neurophysiol. 2009 October; 102(4):2303-11. Marshall L, Helgadottir H, Mölle M, Born J. “Boosting slow oscillations during sleep potentiates memory.” Nature. 2006 Nov. 30; 444(7119):610-3. Marshall L, Kirov R, Brade J, Mölle M, Born J “Transcranial electrical currents to probe EEG brain rhythms and memory consolidation during sleep in humans.” PLoS One. 2011 Feb. 14; 6(2):e16905.

Transcranial Alternative Current Stimulation (tACS) Transcranial alternating current stimulation (tACS) is a noninvasive means by which alternating electrical current applied through the skin and skull entrains in a frequency-specific fashion the neural oscillations of the underlying brain. See, en.wikipedia.org/wiki/Transcranial_alternating_current_stimulation

U.S. Pub. App. No. 20170197081 discloses transdermal electrical stimulation of nerves to modify or induce a cognitive state using transdermal electrical stimulation (TES).

U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 6,804,558; 7,149,773; 7,181,505; 7,278,966; 9,042,201; 9,629,568; 9,713,433; 20010051787; 20020013613; 20020052539; 20020082665; 20050171410; 20140211593; 20140316243; 20150174418; 20150343242; 20160000354; 20160038049; 20160106513; 20160213276; 20160228702; 20160232330; 20160235323; and 20170113056.

Transcranial Random Noise Stimulation (tRNS) Transcranial random noise stimulation (tRNS) is a non-invasive brain stimulation technique and a form of transcranial electrical stimulation (tES). See, en.wikipedia.org/wiki/Transcranial_random_noise_stimulation; U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 9,198,733; 9,713,433; 20140316243; 20160038049; and 20160213276.

Transcranial pulsed current stimulation (IPCS) The stimulus may comprise transcranial pulsed current stimulation (tPCS). See:

Shapour Jaberzadeh, Andisheh Bastani, Maryam Zoghi, “Anodal transcranial pulsed current stimulation: A novel technique to enhance corticospinal excitability,” Clin. Neurophysiology, Volume 125, Issue 2, February 2014, Pages 344-351, doi.org/10.1016/j.clinph.2013.08.025;

earthpulse.net/tpcs-transcranial-pulsed-current-stimulation/; help.foc.us/article/16-tpcs-transcranial-pulsed-current-stimulation.

Transcranial Magnetic Stimulation Transcranial magnetic stimulation (TMS) is a method in which a changing magnetic field is used to cause electric current to flow in a small region of the brain via electromagnetic induction. During a TMS procedure, a magnetic field generator, or “coil”, is placed near the head of the person receiving the treatment. The coil is connected to a pulse generator, or stimulator, that delivers a changing electric current to the coil. TMS is used diagnostically to measure the connection between the central nervous system and skeletal muscle to evaluate damage in a wide variety of disease states, including stroke, multiple sclerosis, amyotrophic lateral sclerosis, movement disorders, and motor neuron diseases. Evidence is available suggesting that TMS is useful in treating neuropathic pain, major depressive disorder, and other conditions.

See, en.wikipedia.org/wiki/Transcranial_magnetic_stimulation,

See U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 4,296,756; 4,367,527; 5,069,218; 5,088,497; 5,359,363; 5,384,588; 5,459,536; 5,711,305; 5,877,801; 5,891,131; 5,954,662; 5,971,923; 6,188,924; 6,259,399; 6,487,441; 6,603,502; 7,714,936; 7,844,324; 7,856,264; 8,221,330; 8,655,817; 8,706,241; 8,725,669; 8,914,115; 9,037,224; 9,042,201; 9,095,266; 9,149,195; 9,248,286; 9,265,458; 9,414,776; 9,445,713; 9,713,433; 20020097332; 20040088732; 20070179534; 20070249949; 20080194981; 20090006001; 20110004412; 20110007129; 20110087127; 20110092882; 20110119212; 20110137371; 20120165696; 20120296569; 20130339043; 20140142654; 20140163328; 20140200432; 20140211593; 20140257047; 20140279746; 20140316243; 20140350369; 20150065803; 20150099946; 20150148617; 20150174418; 20150257700; 20150327813; 20150343242; 20150351655; 20160038049; 20160140306; 20160144175; 20160213276; 20160235323; 20160284082; 20160306942; 20160317077; 20170084175; and 20170113056.

Pulsed electromagnetic field (PEMF) Pulsed electromagnetic field (PEMF) when applied to the brain is referred to as Transcranial magnetic stimulation, and has been FDA approved since 2008 for use in people who failed to respond to antidepressants. Weak magnetic stimulation of the brain is often called transcranial pulsed electromagnetic field (PEMF) therapy. See, en.wikipedia.org/wiki/Pulsed_electromagnetic_field_therapy,

See, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 7,280,861; 8,343,027; 8,415,123; 8,430,805; 8,435,166; 8,571,642; 8,657,732; 8,775,340; 8,961,385; 8,968,172; 9,002,477; 9,005,102; 9,278,231; 9,320,913; 9,339,641; 9,387,338; 9,415,233; 9,427,598; 9,433,797; 9,440,089; 9,610,459; 9,630,004; 9,656,096; 20030181791; 20060129022; 20100057655; 20100197993; 20120101544; 20120116149; 20120143285; 20120253101; 20130013339; 20140213843; 20140213844; 20140221726; 20140228620; 20140303425; 20160235983; 20170087367; and 20170165496.

Deep Brain Stimulation (DBS) Deep brain stimulation (DBS) is a neurosurgical procedure involving the implantation of a medical device called a neurostimulator (sometimes referred to as a ‘brain pacemaker’), which sends electrical impulses, through implanted electrodes, to specific targets in the brain (brain nuclei) for the treatment of movement and neuropsychiatry disorders. See, en.wikipedia.org/wiki/Deep_brain_stimulation.

Transcranial Pulse Ultrasound (TPU) Transcranial pulsed ultrasound (TPU) uses low intensity, low frequency ultrasound (LILFU) as a method to stimulate the brain. See, en.wikipedia.org/wiki/Transcranial_pulsed_ultrasound;

U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 8,591,419; 8,858,440; 8,903,494; 8,921,320; 9,002,458; 9,014,811; 9,036,844; 9,042,201; 9,061,133; 9,233,244; 9,333,334; 9,399,126; 9,403,038; 9,440,070; 9,630,029; 9,669,239; 20120259249; 20120283502; 20120289869; 20130079621; 20130144192; 20130184218; 20140058219; 20140211593; 20140228653; 20140249454; 20140316243; 20150080327; 20150133716; 20150343242; 20160143541; 20160176053; and 20160220850.

Sensory Stimulation Light sound or electromagnetic fields may be used to remotely convey a temporal pattern of brainwaves. See:

U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 5,293,187; 5,422,689; 5,447,166; 5,491,492; 5,546,943; 5,622,168; 5,649,061; 5,720,619; 5,740,812; 5,983,129; 6,050,962; 6,092,058; 6,149,586; 6,325,475; 6,377,833; 6,394,963; 6,428,490; 6,482,165; 6,503,085; 6,520,921; 6,522,906; 6,527,730; 6,556,695; 6,565,518; 6,652,458; 6,652,470; 6,701,173; 6,726,624; 6,743,182; 6,746,409; 6,758,813; 6,843,774; 6,896,655; 6,996,261; 7,037,260; 7,070,571; 7,107,090; 7,120,486; 7,212,851; 7,215,994; 7,260,430; 7,269,455; 7,280,870; 7,392,079; 7,407,485; 7,463,142; 7,478,108; 7,488,294; 7,515,054; 7,567,693; 7,647,097; 7,740,592; 7,751,877; 7,831,305; 7,856,264; 7,881,780; 7,970,734; 7,972,278; 7,974,787; 7,991,461; 8,012,107; 8,032,486; 8,033,996; 8,060,194; 8,095,209; 8,209,224; 8,239,030; 8,262,714; 8,320,649; 8,358,818; 8,376,965; 8,380,316; 8,386,312; 8,386,313; 8,392,250; 8,392,253; 8,392,254; 8,392,255; 8,437,844; 8,464,288; 8,475,371; 8,483,816; 8,494,905; 8,517,912; 8,533,042; 8,545,420; 8,560,041; 8,655,428; 8,672,852; 8,682,687; 8,684,742; 8,694,157; 8,706,241; 8,706,518; 8,738,395; 8,753,296; 8,762,202; 8,764,673; 8,768,022; 8,788,030; 8,790,255; 8,790,297; 8,821,376; 8,838,247; 8,864,310; 8,872,640; 8,888,723; 8,915,871; 8,938,289; 8,938,301; 8,942,813; 8,955,010; 8,955,974; 8,958,882; 8,964,298; 8,971,936; 8,989,835; 8,992,230; 8,998,828; 9,004,687; 9,060,671; 9,101,279; 9,135,221; 9,142,145; 9,165,472; 9,173,582; 9,179,855; 9,208,558; 9,215,978; 9,232,984; 9,241,665; 9,242,067; 9,254,099; 9,271,660; 9,275,191; 9,282,927; 9,292,858; 9,292,920; 9,320,450; 9,326,705; 9,330,206; 9,357,941; 9,396,669; 9,398,873; 9,414,780; 9,414,907; 9,424,761; 9,445,739; 9,445,763; 9,451,303; 9,451,899; 9,454,646; 9,462,977; 9,468,541; 9,483,117; 9,492,120; 9,504,420; 9,504,788; 9,526,419; 9,541,383; 9,545,221; 9,545,222; 9,545,225; 9,560,967; 9,560,984; 9,563,740; 9,582,072; 9,596,224; 9,615,746; 9,622,702; 9,622,703; 9,626,756; 9,629,568; 9,642,699; 9,649,030; 9,651,368; 9,655,573; 9,668,694; 9,672,302; 9,672,617; 9,682,232; 9,693,734; 9,694,155; 9,704,205; 9,706,910; 9,710,788; RE44408; RE45766; 20020024450; 20020103428; 20020103429; 20020112732; 20020128540; 20030028081; 20030028121; 20030070685; 20030083596; 20030100844; 20030120172; 20030149351; 20030158496; 20030158497; 20030171658; 20040019257; 20040024287; 20040068172; 20040092809; 20040101146; 20040116784; 20040143170; 20040267152; 20050010091; 20050019734; 20050025704; 20050038354; 20050113713; 20050124851; 20050148828; 20050228785; 20050240253; 20050245796; 20050267343; 20050267344; 20050283053; 20060020184; 20060061544; 20060078183; 20060087746; 20060102171; 20060129277; 20060161218; 20060189866; 20060200013; 20060241718; 20060252978; 20060252979; 20070050715; 20070179534; 20070191704; 20070238934; 20070273611; 20070282228; 20070299371; 20080004550; 20080009772; 20080058668; 20080081963; 20080119763; 20080123927; 20080132383; 20080228239; 20080234113; 20080234601; 20080242521; 20080255949; 20090018419; 20090058660; 20090062698; 20090076406; 20090099474; 20090112523; 20090221928; 20090267758; 20090270687; 20090270688; 20090270692; 20090270693; 20090270694; 20090270786; 20090281400; 20090287108; 20090297000; 20090299169; 20090311655; 20090312808; 20090312817; 20090318794; 20090326604; 20100004977; 20100010289; 20100010366; 20100041949; 20100069739; 20100069780; 20100163027; 20100163028; 20100163035; 20100165593; 20100168525; 20100168529; 20100168602; 20100268055; 20100293115; 20110004412; 20110009777; 20110015515; 20110015539; 20110043759; 20110054272; 20110077548; 20110092882; 20110105859; 20110130643; 20110172500; 20110218456; 20110256520; 20110270074; 20110301488; 20110307079; 20120004579; 20120021394; 20120036004; 20120071771; 20120108909; 20120108995; 20120136274; 20120150545; 20120203130; 20120262558; 20120271377; 20120310106; 20130012804; 20130046715; 20130063434; 20130063550; 20130080127; 20130120246; 20130127980; 20130185144; 20130189663; 20130204085; 20130211238; 20130226464; 20130242262; 20130245424; 20130281759; 20130289360; 20130293844; 20130308099; 20130318546; 20140058528; 20140155714; 20140171757; 20140200432; 20140214335; 20140221866; 20140243608; 20140243614; 20140243652; 20140276130; 20140276944; 20140288614; 20140296750; 20140300532; 20140303508; 20140304773; 20140313303; 20140315169; 20140316191; 20140316192; 20140316235; 20140316248; 20140323899; 20140335489; 20140343408; 20140347491; 20140350353; 20140350431; 20140364721; 20140378810; 20150002815; 20150003698; 20150003699; 20150005640; 20150005644; 20150006186; 20150012111; 20150038869; 20150045606; 20150051663; 20150099946; 20150112409; 20150120007; 20150124220; 20150126845; 20150126873; 20150133812; 20150141773; 20150145676; 20150154889; 20150174362; 20150196800; 20150213191; 20150223731; 20150234477; 20150235088; 20150235370; 20150235441; 20150235447; 20150241705; 20150241959; 20150242575; 20150242943; 20150243100; 20150243105; 20150243106; 20150247723; 20150247975; 20150247976; 20150248169; 20150248170; 20150248787; 20150248788; 20150248789; 20150248791; 20150248792; 20150248793; 20150290453; 20150290454; 20150305685; 20150306340; 20150309563; 20150313496; 20150313539; 20150324692; 20150325151; 20150335288; 20150339363; 20150351690; 20150366497; 20150366504; 20150366656; 20150366659; 20150369864; 20150370320; 20160000354; 20160004298; 20160005320; 20160007915; 20160008620; 20160012749; 20160015289; 20160022167; 20160022206; 20160029946; 20160029965; 20160038069; 20160051187; 20160051793; 20160066838; 20160073886; 20160077547; 20160078780; 20160106950; 20160112684; 20160120436; 20160143582; 20160166219; 20160167672; 20160176053; 20160180054; 20160198950; 20160199577; 20160202755; 20160216760; 20160220439; 20160228640; 20160232625; 20160232811; 20160235323; 20160239084; 20160248994; 20160249826; 20160256108; 20160267809; 20160270656; 20160287157; 20160302711; 20160306942; 20160313798; 20160317060; 20160317383; 20160324478; 20160324580; 20160334866; 20160338644; 20160338825; 20160339300; 20160345901; 20160357256; 20160360970; 20160363483; 20170000324; 20170000325; 20170000326; 20170000329; 20170000330; 20170000331; 20170000332; 20170000333; 20170000334; 20170000335; 20170000337; 20170000340; 20170000341; 20170000342; 20170000343; 20170000345; 20170000454; 20170000683; 20170001032; 20170006931; 20170007111; 20170007115; 20170007116; 20170007122; 20170007123; 20170007165; 20170007182; 20170007450; 20170007799; 20170007843; 20170010469; 20170010470; 20170017083; 20170020447; 20170020454; 20170020627; 20170027467; 20170027651; 20170027812; 20170031440; 20170032098; 20170035344; 20170043160; 20170055900; 20170060298; 20170061034; 20170071523; 20170071537; 20170071546; 20170071551; 20170080320; 20170086729; 20170095157; 20170099479; 20170100540; 20170103440; 20170112427; 20170112671; 20170113046; 20170113056; 20170119994; 20170135597; 20170135633; 20170136264; 20170136265; 20170143249; 20170143442; 20170148340; 20170156662; 20170162072; 20170164876; 20170164878; 20170168568; 20170173262; 20170173326; 20170177023; 20170188947; 20170202633; 20170209043; 20170209094; and 20170209737.

Light Stimulation The functional relevance of brain oscillations in the alpha frequency range (7.5-12 Hz) has been repeatedly investigated through the use of rhythmic visual stimulation. There are two hypotheses on the origin of steady-state visual evoked potential (SSVEP) measured in EEG during rhythmic stimulation: entrainment of brain oscillations and superposition of event-related responses (ERPs). The entrainment but not the superposition hypothesis justifies rhythmic visual stimulation as a means to manipulate brain oscillations, because superposition assumes a linear summation of single responses, independent from ongoing brain oscillations. Participants stimulated with rhythmic flickering light of different frequencies and intensities, and entrainment was measured by comparing the phase coupling of brain oscillations stimulated by rhythmic visual flicker with the oscillations induced by arrhythmic jittered stimulation, varying the time, stimulation frequency, and intensity conditions. Phase coupling was found to be more pronounced with increasing stimulation intensity as well as at stimulation frequencies closer to each participant's intrinsic frequency. Even in a single sequence of an SSVEP, non-linear features (intermittency of phase locking) was found that contradict the linear summation of single responses, as assumed by the superposition hypothesis. Thus, evidence suggests that visual rhythmic stimulation entrains brain oscillations, validating the approach of rhythmic stimulation as a manipulation of brain oscillations. See, Notbohm A, Kurths J, Herrmann C S, Modification of Brain Oscillations via Rhythmic Light Stimulation Provides Evidence for Entrainment but Not for Superposition of Event-Related Responses, Front Hum Neurosci. 2016 Feb. 3; 10:10. doi: 10.3389/fnhum.2016.00010. eCollection 2016.

It is also known that periodic visual stimulation can trigger epileptic seizures.

Cochlear Implant A cochlear implant is a surgically implanted electronic device that provides a sense of sound to a person who is profoundly deaf or severely hard of hearing in both ears. See, en.wikipedia.org/wiki/Cochlear_implant;

See, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 5,999,856; 6,354,299; 6,427,086; 6,430,443; 6,665,562; 6,873,872; 7,359,837; 7,440,806; 7,493,171; 7,610,083; 7,610,100; 7,702,387; 7,747,318; 7,765,088; 7,853,321; 7,890,176; 7,917,199; 7,920,916; 7,957,806; 8,014,870; 8,024,029; 8,065,017; 8,108,033; 8,108,042; 8,140,152; 8,165,687; 8,175,700; 8,195,295; 8,209,018; 8,224,431; 8,315,704; 8,332,024; 8,401,654; 8,433,410; 8,478,417; 8,515,541; 8,538,543; 8,560,041; 8,565,864; 8,574,164; 8,577,464; 8,577,465; 8,577,466; 8,577,467; 8,577,468; 8,577,472; 8,577,478; 8,588,941; 8,594,800; 8,644,946; 8,644,957; 8,652,187; 8,676,325; 8,696,724; 8,700,183; 8,718,776; 8,768,446; 8,768,477; 8,788,057; 8,798,728; 8,798,773; 8,812,126; 8,864,806; 8,868,189; 8,929,999; 8,968,376; 8,989,868; 8,996,120; 9,002,471; 9,044,612; 9,061,132; 9,061,151; 9,095,713; 9,135,400; 9,186,503; 9,235,685; 9,242,067; 9,248,290; 9,248,291; 9,259,177; 9,302,093; 9,314,613; 9,327,069; 9,352,145; 9,352,152; 9,358,392; 9,358,393; 9,403,009; 9,409,013; 9,415,215; 9,415,216; 9,421,372; 9,432,777; 9,501,829; 9,526,902; 9,533,144; 9,545,510; 9,550,064; 9,561,380; 9,578,425; 9,592,389; 9,604,067; 9,616,227; 9,643,017; 9,649,493; 9,674,621; 9,682,232; 9,743,197; 9,744,358; 20010014818; 20010029391; 20020099412; 20030114886; 20040073273; 20050149157; 20050182389; 20050182450; 20050182467; 20050182468; 20050182469; 20050187600; 20050192647; 20050209664; 20050209665; 20050209666; 20050228451; 20050240229; 20060064140; 20060094970; 20060094971; 20060094972; 20060095091; 20060095092; 20060161217; 20060173259; 20060178709; 20060195039; 20060206165; 20060235484; 20060235489; 20060247728; 20060282123; 20060287691; 20070038264; 20070049988; 20070156180; 20070198063; 20070213785; 20070244407; 20070255155; 20070255531; 20080049376; 20080140149; 20080161886; 20080208280; 20080235469; 20080249589; 20090163980; 20090163981; 20090243756; 20090259277; 20090270944; 20090280153; 20100030287; 20100100164; 20100198282; 20100217341; 20100231327; 20100241195; 20100268055; 20100268288; 20100318160; 20110004283; 20110060382; 20110166471; 20110295344; 20110295345; 20110295346; 20110295347; 20120035698; 20120116179; 20120116741; 20120150255; 20120245655; 20120262250; 20120265270; 20130165996; 20130197944; 20130235550; 20140032512; 20140098981; 20140200623; 20140249608; 20140275847; 20140330357; 20140350634; 20150018699; 20150045607; 20150051668; 20150065831; 20150066124; 20150080674; 20150328455; 20150374986; 20150374987; 20160067485; 20160243362; 20160261962; 20170056655; 20170087354; 20170087355; 20170087356; 20170113046; 20170117866; 20170135633; and 20170182312.

Vagus Nerve Stimulation Vagus nerve stimulation (VNS) is a medical treatment that involves delivering electrical impulses to the vagus nerve. It is used as an adjunctive treatment for certain types of intractable epilepsy and treatment-resistant depression.

See, en.wikipedia.org/wiki/Vagus_nerve_stimulation;

See, U.S. Patent and Pub. Pat Nos. U.S. Pat. Nos. 5,215,086; 5,231,988; 5,299,569; 5,335,657; 5,571,150; 5,928,272; 5,995,868; 6,104,956; 6,167,311; 6,205,359; 6,208,902; 6,248,126; 6,269,270; 6,339,725; 6,341,236; 6,356,788; 6,366,814; 6,418,344; 6,497,699; 6,549,804; 6,556,868; 6,560,486; 6,587,727; 6,591,137; 6,597,954; 6,609,030; 6,622,047; 6,665,562; 6,671,556; 6,684,105; 6,708,064; 6,735,475; 6,782,292; 6,788,975; 6,873,872; 6,879,859; 6,882,881; 6,920,357; 6,961,618; 7,003,352; 7,151,961; 7,155,279; 7,167,751; 7,177,678; 7,203,548; 7,209,787; 7,228,167; 7,231,254; 7,242,984; 7,277,758; 7,292,890; 7,313,442; 7,324,851; 7,346,395; 7,366,571; 7,386,347; 7,389,144; 7,403,820; 7,418,290; 7,422,555; 7,444,184; 7,454,245; 7,457,665; 7,463,927; 7,486,986; 7,493,172; 7,499,752; 7,561,918; 7,620,455; 7,623,927; 7,623,928; 7,630,757; 7,634,317; 7,643,881; 7,653,433; 7,657,316; 7,676,263; 7,680,526; 7,684,858; 7,706,871; 7,711,432; 7,734,355; 7,736,382; 7,747,325; 7,747,326; 7,769,461; 7,783,362; 7,801,601; 7,805,203; 7,840,280; 7,848,803; 7,853,321; 7,853,329; 7,860,548; 7,860,570; 7,865,244; 7,869,867; 7,869,884; 7,869,885; 7,890,185; 7,894,903; 7,899,539; 7,904,134; 7,904,151; 7,904,175; 7,908,008; 7,920,915; 7,925,353; 7,945,316; 7,957,796; 7,962,214; 7,962,219; 7,962,220; 7,974,688; 7,974,693; 7,974,697; 7,974,701; 7,996,079; 8,000,788; 8,027,730; 8,036,745; 8,041,418; 8,041,419; 8,046,076; 8,064,994; 8,068,911; 8,097,926; 8,108,038; 8,112,148; 8,112,153; 8,116,883; 8,150,508; 8,150,524; 8,160,696; 8,172,759; 8,180,601; 8,190,251; 8,190,264; 8,204,603; 8,209,009; 8,209,019; 8,214,035; 8,219,188; 8,224,444; 8,224,451; 8,229,559; 8,239,028; 8,260,426; 8,280,505; 8,306,627; 8,315,703; 8,315,704; 8,326,418; 8,337,404; 8,340,771; 8,346,354; 8,352,031; 8,374,696; 8,374,701; 8,379,952; 8,382,667; 8,401,634; 8,412,334; 8,412,338; 8,417,344; 8,423,155; 8,428,726; 8,452,387; 8,454,555; 8,457,747; 8,467,878; 8,478,428; 8,485,979; 8,489,185; 8,498,699; 8,515,538; 8,536,667; 8,538,523; 8,538,543; 8,548,583; 8,548,594; 8,548,604; 8,560,073; 8,562,536; 8,562,660; 8,565,867; 8,571,643; 8,571,653; 8,588,933; 8,591,419; 8,600,521; 8,603,790; 8,606,360; 8,615,309; 8,630,705; 8,634,922; 8,641,646; 8,644,954; 8,649,871; 8,652,187; 8,660,666; 8,666,501; 8,676,324; 8,676,330; 8,684,921; 8,694,118; 8,700,163; 8,712,547; 8,716,447; 8,718,779; 8,725,243; 8,738,126; 8,744,562; 8,761,868; 8,762,065; 8,768,471; 8,781,597; 8,815,582; 8,827,912; 8,831,732; 8,843,210; 8,849,409; 8,852,100; 8,855,775; 8,858,440; 8,864,806; 8,868,172; 8,868,177; 8,874,205; 8,874,218; 8,874,227; 8,888,702; 8,914,122; 8,918,178; 8,934,967; 8,942,817; 8,945,006; 8,948,855; 8,965,514; 8,968,376; 8,972,004; 8,972,013; 8,983,155; 8,983,628; 8,983,629; 8,985,119; 8,989,863; 8,989,867; 9,014,804; 9,014,823; 9,020,582; 9,020,598; 9,020,789; 9,026,218; 9,031,655; 9,042,201; 9,042,988; 9,043,001; 9,044,188; 9,050,469; 9,056,195; 9,067,054; 9,067,070; 9,079,940; 9,089,707; 9,089,719; 9,095,303; 9,095,314; 9,108,041; 9,113,801; 9,119,533; 9,135,400; 9,138,580; 9,162,051; 9,162,052; 9,174,045; 9,174,066; 9,186,060; 9,186,106; 9,204,838; 9,204,998; 9,220,910; 9,233,246; 9,233,258; 9,235,685; 9,238,150; 9,241,647; 9,242,067; 9,242,092; 9,248,286; 9,249,200; 9,249,234; 9,254,383; 9,259,591; 9,265,660; 9,265,661; 9,265,662; 9,265,663; 9,265,931; 9,265,946; 9,272,145; 9,283,394; 9,284,353; 9,289,599; 9,302,109; 9,309,296; 9,314,633; 9,314,635; 9,320,900; 9,326,720; 9,332,939; 9,333,347; 9,339,654; 9,345,886; 9,358,381; 9,359,449; 9,364,674; 9,365,628; 9,375,571; 9,375,573; 9,381,346; 9,394,347; 9,399,133; 9,399,134; 9,402,994; 9,403,000; 9,403,001; 9,403,038; 9,409,022; 9,409,028; 9,415,219; 9,415,222; 9,427,581; 9,440,063; 9,458,208; 9,468,761; 9,474,852; 9,480,845; 9,492,656; 9,492,678; 9,501,829; 9,504,390; 9,505,817; 9,522,085; 9,522,282; 9,526,902; 9,533,147; 9,533,151; 9,538,951; 9,545,226; 9,545,510; 9,561,380; 9,566,426; 9,579,506; 9,586,047; 9,592,003; 9,592,004; 9,592,409; 9,604,067; 9,604,073; 9,610,442; 9,622,675; 9,623,240; 9,643,017; 9,643,019; 9,656,075; 9,662,069; 9,662,490; 9,675,794; 9,675,809; 9,682,232; 9,682,241; 9,700,256; 9,700,716; 9,700,723; 9,707,390; 9,707,391; 9,717,904; 9,729,252; 9,737,230; 20010003799; 20010029391; 20020013612; 20020072776; 20020072782; 20020099417; 20020099418; 20020151939; 20030023282; 20030045914; 20030083716; 20030114886; 20030181954; 20030195574; 20030236557; 20030236558; 20040015204; 20040015205; 20040073273; 20040138721; 20040153129; 20040172089; 20040172091; 20040172094; 20040193220; 20040243182; 20040260356; 20050027284; 20050033379; 20050043774; 20050049651; 20050137645; 20050149123; 20050149157; 20050154419; 20050154426; 20050165458; 20050182288; 20050182450; 20050182453; 20050182467; 20050182468; 20050182469; 20050187600; 20050192644; 20050192647; 20050197590; 20050197675; 20050197678; 20050209654; 20050209664; 20050209665; 20050209666; 20050216070; 20050216071; 20050251220; 20050267542; 20060009815; 20060047325; 20060052657; 20060064138; 20060064139; 20060064140; 20060079936; 20060111644; 20060129202; 20060142802; 20060155348; 20060167497; 20060173493; 20060173494; 20060173495; 20060195154; 20060206155; 20060212090; 20060212091; 20060217781; 20060224216; 20060259077; 20060282123; 20060293721; 20060293723; 20070005115; 20070021800; 20070043401; 20070060954; 20070060984; 20070066997; 20070067003; 20070067004; 20070093870; 20070100377; 20070100378; 20070100392; 20070112404; 20070150024; 20070150025; 20070162085; 20070173902; 20070198063; 20070213786; 20070233192; 20070233193; 20070255320; 20070255379; 20080021341; 20080027347; 20080027348; 20080027515; 20080033502; 20080039904; 20080065183; 20080077191; 20080086182; 20080091240; 20080125829; 20080140141; 20080147137; 20080154332; 20080161894; 20080167571; 20080183097; 20080269542; 20080269833; 20080269834; 20080269840; 20090018462; 20090036950; 20090054946; 20090088680; 20090093403; 20090118780; 20090163982; 20090171405; 20090187230; 20090234419; 20090276011; 20090276012; 20090280153; 20090326605; 20100003656; 20100004705; 20100004717; 20100057159; 20100063563; 20100106217; 20100114190; 20100114192; 20100114193; 20100125219; 20100125304; 20100145428; 20100191304; 20100198098; 20100198296; 20100204749; 20100268288; 20100274303; 20100274308; 20100292602; 20110009920; 20110021899; 20110028799; 20110029038; 20110029044; 20110034912; 20110054569; 20110077721; 20110092800; 20110098778; 20110105998; 20110125203; 20110130615; 20110137381; 20110152967; 20110152988; 20110160795; 20110166430; 20110166546; 20110172554; 20110172725; 20110172732; 20110172739; 20110178441; 20110178442; 20110190569; 20110201944; 20110213222; 20110224602; 20110224749; 20110230701; 20110230938; 20110257517; 20110264182; 20110270095; 20110270096; 20110270346; 20110270347; 20110276107; 20110276112; 20110282225; 20110295344; 20110295345; 20110295346; 20110295347; 20110301529; 20110307030; 20110311489; 20110319975; 20120016336; 20120016432; 20120029591; 20120029601; 20120046711; 20120059431; 20120078323; 20120083700; 20120083701; 20120101326; 20120116741; 20120158092; 20120179228; 20120184801; 20120185020; 20120191158; 20120203079; 20120209346; 20120226130; 20120232327; 20120265262; 20120303080; 20120310050; 20120316622; 20120330369; 20130006332; 20130018438; 20130018439; 20130018440; 20130019325; 20130046358; 20130066350; 20130066392; 20130066395; 20130072996; 20130089503; 20130090454; 20130096441; 20130131753; 20130165846; 20130178913; 20130184639; 20130184792; 20130204144; 20130225953; 20130225992; 20130231721; 20130238049; 20130238050; 20130238053; 20130244323; 20130245464; 20130245486; 20130245711; 20130245712; 20130253612; 20130261703; 20130274625; 20130281890; 20130289653; 20130289669; 20130296406; 20130296637; 20130304159; 20130309278; 20130310909; 20130317580; 20130338450; 20140039290; 20140039336; 20140039578; 20140046203; 20140046407; 20140052213; 20140056815; 20140058189; 20140058292; 20140074188; 20140081071; 20140081353; 20140094720; 20140100633; 20140107397; 20140107398; 20140113367; 20140128938; 20140135680; 20140135886; 20140142653; 20140142654; 20140142669; 20140155772; 20140155952; 20140163643; 20140213842; 20140213961; 20140214135; 20140235826; 20140236272; 20140243613; 20140243714; 20140257118; 20140257132; 20140257430; 20140257437; 20140257438; 20140275716; 20140276194; 20140277255; 20140277256; 20140288620; 20140303452; 20140324118; 20140330334; 20140330335; 20140330336; 20140336514; 20140336730; 20140343463; 20140357936; 20140358067; 20140358193; 20140378851; 20150005592; 20150005839; 20150012054; 20150018893; 20150025422; 20150032044; 20150032178; 20150051655; 20150051656; 20150051657; 20150051658; 20150051659; 20150057715; 20150072394; 20150073237; 20150073505; 20150119689; 20150119794; 20150119956; 20150142082; 20150148878; 20150157859; 20150165226; 20150174398; 20150174405; 20150174407; 20150182753; 20150182756; 20150190636; 20150190637; 20150196246; 20150202428; 20150208978; 20150216469; 20150231330; 20150238761; 20150265830; 20150265836; 20150283265; 20150297719; 20150297889; 20150306392; 20150343222; 20150352362; 20150360030; 20150366482; 20150374973; 20150374993; 20160001096; 20160008620; 20160012749; 20160030666; 20160045162; 20160045731; 20160051818; 20160058359; 20160074660; 20160081610; 20160114165; 20160121114; 20160121116; 20160135727; 20160136423; 20160144175; 20160151628; 20160158554; 20160175607; 20160199656; 20160199662; 20160206236; 20160222073; 20160232811; 20160243381; 20160249846; 20160250465; 20160263376; 20160279021; 20160279022; 20160279023; 20160279024; 20160279025; 20160279267; 20160279410; 20160279435; 20160287869; 20160287895; 20160303396; 20160303402; 20160310070; 20160331952; 20160331974; 20160331982; 20160339237; 20160339238; 20160339239; 20160339242; 20160346542; 20160361540; 20160361546; 20160367808; 20160375245; 20170007820; 20170027812; 20170043160; 20170056467; 20170056642; 20170066806; 20170079573; 20170080050; 20170087364; 20170095199; 20170095670; 20170113042; 20170113057; 20170120043; 20170120052; 20170143550; 20170143963; 20170143986; 20170150916; 20170150921; 20170151433; 20170157402; 20170164894; 20170189707; 20170198017; and 20170224994.

Brain-To-Brain Interface A brain-brain interface is a direct communication pathway between the brain of one animal and the brain of another animal. Brain to brain interfaces have been used to help rats collaborate with each other. When a second rat was unable to choose the correct lever, the first rat noticed (not getting a second reward), and produced a round of task-related neuron firing that made the second rat more likely to choose the correct lever. Human studies have also been conducted.

In 2013, researcher from the University of Washington were able to use electrical brain recordings and a form of magnetic stimulation to send a brain signal to a recipient, which caused the recipient to hit the fire button on a computer game. In 2015, researchers linked up multiple brains, of both monkeys and rats, to form an “organic computer.” It is hypothesized that by using brain-to-brain interfaces (BTBIs) a biological computer, or brain-net could be constructed using animal brains as its computational units. Initial exploratory work demonstrated collaboration between rats in distant cages linked by signals from cortical microelectrode arrays implanted in their brains. The rats were rewarded when actions were performed by the “decoding rat” which conformed to incoming signals and when signals were transmitted by the “encoding rat” which resulted in the desired action. In the initial experiment the rewarded action was pushing a lever in the remote location corresponding to the position of a lever near a lighted LED at the home location. About a month was required for the rats to acclimate themselves to incoming “brainwaves.” When a decoding rat was unable to choose the correct lever, the encoding rat noticed (not getting an expected reward), and produced a round of task-related neuron firing that made the second rat more likely to choose the correct lever.

In another study, electrical brain readings were used to trigger a form of magnetic stimulation, to send a brain signal based on brain activity on a subject to a recipient, which caused the recipient to hit the fire button on a computer game.

Brain-To-Computer Interface A brain-computer interface (BCI), sometimes called a neural-control interface (NCI), mind-machine interface (MMI), direct neural interface (DNI), or brain-machine interface (BMI), is a direct communication pathway between an enhanced or wired brain and an external device. BCI differs from neuromodulation in that it allows for bidirectional information flow. BCIs are often directed at researching, mapping, assisting, augmenting, a repairing human cognitive or sensory-motor functions.

Synthetic telepathy, also known as techlepathy or psychotronics (geeldon.wordpress.com/2010/09/06/synthetic-telepathy-also-known-as-techlepathy-or-psychotronics/), describes the process of use of brain-computer interfaces by which human thought (as electromagnetic radiation) is intercepted, processed by computer and a return signal generated that is perceptible by the human brain. Dewan, E. M., “Occipital Alpha Rhythm Eye Position and Lens Accommodation.” Nature 214, 975-977 (3 Jun. 1967), demonstrates the mental control of Alpha waves, turning them on and off, to produce Morse code representations of words and phrases by thought alone. U.S. Pat. No. 3,951,134 proposes remotely monitoring and altering brainwaves using radio, and references demodulating the waveform, displaying it to an operator for viewing and passing this to a computer for further analysis. In 1988, Farwell, L. A. & Donchin, E. (1988). Talking off the top of your head: toward a mental prosthesis utilizing event-related brain potentials. Electroencephalography and Clinical Neurophysiology, 70(6), 510-523 describes a method of transmitting linguistic information using the P300 response system, which combines matching observed information to what the subject was thinking of. In this case, being able to select a letter of the alphabet that the subject was thinking of. In theory, any input could be used and a lexicon constructed. U.S. Pat. No. 6,011,991 describes a method of monitoring an individual's brainwaves remotely, for the purposes of communication, and outlines a system that monitors an individual's brainwaves via a sensor, then transmits this information, specifically by satellite, to a computer for analysis. This analysis would determine if the individual was attempting to communicate a “word, phrase, or thought corresponding to the matched stored normalized signal.”

Approaches to synthetic telepathy can be categorized into two major groups, passive and active. Like sonar, the receiver can take part or passively listen. Passive reception is the ability to “read” a signal without first broadcasting a signal. This can be roughly equated to tuning into a radio station—the brain generates electromagnetic radiation which can be received at a distance. That distance is determined by the sensitivity of the receiver, the filters used and the bandwidth required. Most universities would have limited budgets, and receivers, such as EEG (and similar devices), would be used. A related military technology is the surveillance system TEMPEST. Robert G. Malech's approach requires a modulated signal to be broadcast at the target. The method uses an active signal, which is interfered with by the brain's modulation. Thus, the return signal can be used to infer the original brainwave.

Computer mediation falls into two basic categories, interpretative and interactive. Interpretative mediation is the passive analysis of signals coming from the human brain. A computer “reads” the signal then compares that signal against a database of signals and their meanings. Using statistical analysis and repetition, false-positives are reduced overtime. Interactive mediation can be in a passive-active mode a active-active mode. In this case, passive and active denote the method of reading and writing to the brain and whether or not they make use of a broadcast signal. Interactive mediation can also be performed manually or via artificial intelligence. Manual interactive mediation involves a human operator producing return signals such as speech or images. AI mediation leverages the cognitive system of the subject to identify images, pre-speech, objects, sounds and other artifacts, rather than developing AI routines to perform such activities. AI based systems may incorporate natural language processing interfaces that produce sensations, mental impressions, humor and conversation to provide a mental picture of a computerized personality. Statistical analysis and ML techniques, such as neural networks can be used.

ITV News Service (March 1991), reported ultrasound piggybacked on a commercial radio broadcast (100 MHz) aimed at entraining the brains of Iraqi troops and creating feelings of despair. U.S. Pat. No. 5,159,703 that refers to a “silent communications system in which nonaural carriers, in the very low a very high audio frequency range or in the adjacent ultrasonic frequency spectrum, are amplitude or frequency modulated with the desired intelligence and propagated acoustically or vibrational, for inducement into the brain, typically through the use of loudspeakers, earphones or piezoelectric transducers.” See:

Dr Nick Begich—Controlling the Human Mind, Earth Pulse Press Anchorage—isbn=1-890693-54-5

cbcg.org/gjcs1.htm%7C God's Judgment Cometh Soon

cnslab.ss.ud.edu/muri/research.html, #Dewan, #FarwellDonchin, #lmaginedSpeechProduction, #Overview, MURI: Synthetic Telepathy

daprocess.com/01.welcome.html DaProcess of A Federal Investigation

deepthoughtnewsvine.com/_news/2012/01/01/9865851-nsa-disinformation-watch-the-watchers-with-me

deepthoughtnewsvine.com/_news/2012/01/09/10074589-nsa-disinformation-watch-the-watchers-with-me-part-2

deepthoughtnewsvine.com/_news/2012/01/16/10169491-the-nsa-behind-the-curtain

genamason.wordpress.com/2009/10/18/more-on-synthetic-telepathy/

io9.com/5065304/tips-and-tricks-for-mind-control-from-the-us-military

newdawnmagazine.com.au/Article/Brain_Zapping_Part_One.html

pinktentacle.com/2008/12/scientists-extract-images-directly-from-brain/Scientists extract images directly from brain

timesofindia.indiatimes.com/HealthSci/US_army_developing_synthetic_telepathy/

www.bibliotecapleyades.net/ciencia/ciencia_nonlethalweapons02.htm Eleanor White—New Devices That ‘Talk’ To The Human Mind Need Debate, Controls

www.cbsnews.com/stories/2008/12/31/60minutes/main4694713.shtml60 Minutes: Incredible Research Lets Scientists Get A Glimpse At Your Thoughts

www.cbsnews.com/video/watch/?id=5119805n&amp;tag=related;photovideo 60 Minutes: Video—Mind Reading

www.charlesrehn.com/charlesrehn/books/aconversationwithamerica/essays/myessays/The%20NSA.doc

www.govtrack.us/congress/billtext.xpd?bill=h107-2977 Space Preservation Act of 2001

www.informaworld.com/smpp/content˜db=all˜content=a785359968 Partial Amnesia for a Narrative Following Application of Theta Frequency Electromagnetic Fields

www.msnbc.msn.com/id/27162401/

www.psychology.nottingham.ac.uk/staff/lpxdts/TMS%20info.html Transcranial Magnetic Stimulation

www.raven1.net/silsoun2.htm Psy-Ops Weaponry Used In The Persian Gulf War

www.scribd.com/doc/24531011/Operation-Mind-Control

www.scribd.com/doc/6508206/synthetic-telepathy-and-the-early-mind-wars

www.slavery.org.uk/Bioeffects_of_Selected_Non-Lethal_Weapons.pdf-Bioeffects of selected non-lethal weapons

www.sst.ws/tempstandards.php?pab=1_1 TEMPEST measurement standards

www.uwe.ac.uk/hlss/research/cpss/Journal_Psycho-Social_Studies/v2-2/SmithC.shtml Journal of Psycho-Social Studies—Vol 2 (2) 2003—On the Need for New Criteria of Diagnosis of Psychosis in the Light of Mind Invasive Technology by Dr. Carole Smith

www.wired.com/dangerroom/2009/05/pentagon-preps-soldier-telepathy-push

www.wired.com/wired/archive/7.11/persinger.html This Is Your Brain on God

Noah, Shachtman—Pentagon's PCs Bend to Your Brain www.wired.com/dangerroom/2007/03/the_us_military

Soldier-Telepathy” Drummond, Katie—Pentagon Preps Soldier Telepathy Push U.S. Pat. No. 3,951,134

U.S. Pat. No. 5,159,703 Silent subliminal presentation system

U.S. Pat. No. 6,011,991

U.S. Pat. No. 6,587,729 Apparatus for audibly communicating speech using the radio frequency hearing effect

Wall, Judy, “Military Use of Mind Control Weapons”, NEXUS, 5/06, October-November 1998

It is known to analyze EEG patterns to extract an indication of certain volitional activity (U.S. Pat. No. 6,011,991). This technique describes that an EEG recording can be matched against a stored normalized signal using a computer. This matched signal is then translated into the corresponding reference. The patent application describes a method “a system capable of identifying particular nodes in an individual's brain, the firings of which affect characteristics such as appetite, hunger, thirst, communication skills” and “devices mounted to the person (e.g. underneath the scalp) may be energized in a predetermined manner or sequence to remotely cause particular identified brain node(s) to be fired in order to cause a predetermined feeling or reaction in the individual” without technical description of implementation. This patent also describes, that “brain activity (is monitored) by way of electroencephalograph (EEG) methods, magnetoencephalograph (MEG) methods, and the like. For example, see U.S. Pat. Nos. 5,816,247 and 5,325,862.

See also, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 3,951,134; 4,437,064; 4,591,787; 4,613,817; 4,689,559; 4,693,000; 4,700,135; 4,733,180; 4,736,751; 4,749,946; 4,753,246; 4,761,611; 4771,239; 4,801,882; 4,862,359; 4,913,152; 4,937,525; 4,940,058; 4,947,480; 4,949,725; 4,951,674; 4,974,602; 4,982,157; 4,983,912; 4,996,479; 5,008,622; 5,012,190; 5,020,538; 5,061,680; 5,092,835; 5,095,270; 5,126,315; 5,158,932; 5,159,703; 5,159,928; 5,166,614; 5,187,327; 5,198,977; 5,213,338; 5,241,967; 5,243,281; 5,243,517; 5,263,488; 5,265,611; 5,269,325; 5,282,474; 5,283,523; 5,291,888; 5,303,705; 5,307,807; 5,309,095; 5,311,129; 5,323,777; 5,325,862; 5,326,745; 5,339,811; 5,417,211; 5,418,512; 5,442,289; 5,447,154; 5,458,142; 5,469,057; 5,476,438; 5,496,798; 5,513,649; 5,515,301; 5,552,375; 5,579,241; 5,594,849; 5,600,243; 5,601,081; 5,617,856; 5,626,145; 5,656,937; 5,671,740; 5,682,889; 5,701,909; 5,706,402; 5,706,811; 5,729,046; 5,743,854; 5,743,860; 5,752,514; 5,752,911; 5,755,227; 5,761,332; 5,762,611; 5,767,043; 5,771,261; 5,771,893; 5,771,894; 5,797,853; 5,813,993; 5,815,413; 5,842,986; 5,857,978; 5,885,976; 5,921,245; 5,938,598; 5,938,688; 5,970,499; 6,002,254; 6,011,991; 6,023,161; 6,066,084; 6,069,369; 6,080,164; 6,099,319; 6,144,872; 6,154,026; 6,155,966; 6,167,298; 6,167,311; 6,195,576; 6,230,037; 6,239,145; 6,263,189; 6,290,638; 6,354,087; 6,356,079; 6,370,414; 6,374,131; 6,385,479; 6,418,344; 6,442,948; 6,470,220; 6,488,617; 6,516,246; 6,526,415; 6,529,759; 6,538,436; 6,539,245; 6,539,263; 6,544,170; 6,547,746; 6,557,558; 6,587,729; 6,591,132; 6,609,030; 6,611,698; 6,648,822; 6,658,287; 6,665,552; 6,665,553; 6,665,562; 6,684,098; 6,687,525; 6,695,761; 6,697,660; 6,708,051; 6,708,064; 6,708,184; 6,725,080; 6,735,460; 6,774,929; 6,785,409; 6,795,724; 6,804,661; 6,815,949; 6,853,186; 6,856,830; 6,873,872; 6,876,196; 6,885,192; 6,907,280; 6,926,921; 6,947,790; 6,978,179; 6,980,863; 6,983,184; 6,983,264; 6,996,261; 7,022,083; 7,023,206; 7,024,247; 7,035,686; 7,038,450; 7,039,266; 7,039,547; 7,053,610; 7,062,391; 7,092,748; 7,105,824; 7,116,102; 7,120,486; 7,130,675; 7,145,333; 7,171,339; 7,176,680; 7,177,675; 7,183,381; 7,186,209; 7,187,169; 7,190,826; 7,193,413; 7,196,514; 7,197,352; 7,199,708; 7,209,787; 7,218,104; 7,222,964; 7,224,282; 7,228,178; 7,231,254; 7,242,984; 7,254,500; 7,258,659; 7,269,516; 7,277,758; 7,280,861; 7,286,871; 7,313,442; 7,324,851; 7,334,892; 7,338,171; 7,340,125; 7,340,289; 7,346,395; 7,353,064; 7,353,065; 7,369,896; 7,371,365; 7,376,459; 7,394,246; 7,400,984; 7,403,809; 7,403,820; 7,409,321; 7,418,290; 7,420,033; 7,437,196; 7,440,789; 7,453,263; 7,454,387; 7,457,653; 7,461,045; 7,462,155; 7,463,024; 7,466,132; 7,468,350; 7,482,298; 7,489,964; 7,502,720; 7,539,528; 7,539,543; 7,553,810; 7,565,200; 7,565,809; 7,567,693; 7,570,054; 7,573,264; 7,573,268; 7,580,798; 7,603,174; 7,608,579; 7,613,502; 7,613,519; 7,613,520; 7,620,456; 7,623,927; 7,623,928; 7,625,340; 7,627,370; 7,647,098; 7,649,351; 7,653,433; 7,672,707; 7,676,263; 7,678,767; 7,697,979; 7,706,871; 7,715,894; 7,720,519; 7,729,740; 7,729,773; 7,733,973; 7,734,340; 7,737,687; 7,742,820; 7,746,979; 7,747,325; 7,747,326; 7,747,551; 7,756,564; 7,763,588; 7,769,424; 7,771,341; 7,792,575; 7,800,493; 7,801,591; 7,801,686; 7,831,305; 7,834,627; 7,835,787; 7,840,039; 7,840,248; 7,840,250; 7,853,329; 7,856,264; 7,860,552; 7,873,411; 7,881,760; 7,881,770; 7,882,135; 7,891,814; 7,892,764; 7,894,903; 7,895,033; 7,904,139; 7,904,507; 7,908,009; 7,912,530; 7,917,221; 7,917,225; 7,929,693; 7,930,035; 7,932,225; 7,933,727; 7,937,152; 7,945,304; 7,962,204; 7,974,787; 7,986,991; 7,988,969; 8,000,767; 8,000,794; 8,001,179; 8,005,894; 8,010,178; 8,014,870; 8,027,730; 8,029,553; 8,032,209; 8,036,736; 8,055,591; 8,059,879; 8,065,360; 8,069,125; 8,073,631; 8,082,215; 8,083,786; 8,086,563; 8,116,874; 8,116,877; 8,121,694; 8,121,695; 8,150,523; 8,150,796; 8,155,726; 8,160,273; 8,185,382; 8,190,248; 8,190,264; 8,195,593; 8,209,224; 8,212,556; 8,222,378; 8,224,433; 8,229,540; 8,239,029; 8,244,552; 8,244,553; 8,248,069; 8,249,316; 8,270,814; 8,280,514; 8,285,351; 8,290,596; 8,295,934; 8,301,222; 8,301,257; 8,303,636; 8,304,246; 8,305,078; 8,308,646; 8,315,703; 8,334,690; 8,335,715; 8,335,716; 8,337,404; 8,343,066; 8,346,331; 8,350,804; 8,354,438; 8,356,004; 8,364,271; 8,374,412; 8,374,696; 8,380,314; 8,380,316; 8,380,658; 8,386,312; 8,386,313; 8,388,530; 8,392,250; 8,392,251; 8,392,253; 8,392,254; 8,392,255; 8,396,545; 8,396,546; 8,396,744; 8,401,655; 8,406,838; 8,406,848; 8,412,337; 8,423,144; 8,423,297; 8,429,225; 8,431,537; 8,433,388; 8,433,414; 8,433,418; 8,439,845; 8,444,571; 8,445,021; 8,447,407; 8,456,164; 8,457,730; 8,463,374; 8,463,378; 8,463,386; 8,463,387; 8,464,288; 8,467,878; 8,473,345; 8,483,795; 8,484,081; 8,487,760; 8,492,336; 8,494,610; 8,494,857; 8,494,905; 8,498,697; 8,509,904; 8,519,705; 8,527,029; 8,527,035; 8,529,463; 8,532,756; 8,532,757; 8,533,042; 8,538,513; 8,538,536; 8,543,199; 8,548,786; 8,548,852; 8,553,956; 8,554,325; 8,559,645; 8,562,540; 8,562,548; 8,565,606; 8,568,231; 8,571,629; 8,574,279; 8,586,019; 8,587,304; 8,588,933; 8,591,419; 8,593,141; 8,600,493; 8,600,696; 8,603,790; 8,606,592; 8,612,005; 8,613,695; 8,613,905; 8,614,254; 8,614,873; 8,615,293; 8,615,479; 8,615,664; 8,618,799; 8,626,264; 8,628,328; 8,635,105; 8,648,017; 8,652,189; 8,655,428; 8,655,437; 8,655,817; 8,658,149; 8,660,649; 8,666,099; 8,679,009; 8,682,441; 8,690,748; 8,693,765; 8,700,167; 8,703,114; 8,706,205; 8,706,206; 8,706,241; 8,706,518; 8,712,512; 8,716,447; 8,721,695; 8,725,243; 8,725,668; 8,725,669; 8,725,796; 8,731,650; 8,733,290; 8,738,395; 8,762,065; 8,762,202; 8,768,427; 8,768,447; 8,781,197; 8,781,597; 8,786,624; 8,798,717; 8,814,923; 8,815,582; 8,825,167; 8,838,225; 8,838,247; 8,845,545; 8,849,390; 8,849,392; 8,855,775; 8,858,440; 8,868,173; 8,874,439; 8,888,702; 8,893,120; 8,903,494; 8,907,668; 8,914,119; 8,918,176; 8,922,376; 8,933,696; 8,934,965; 8,938,289; 8,948,849; 8,951,189; 8,951,192; 8,954,293; 8,955,010; 8,961,187; 8,974,365; 8,977,024; 8,977,110; 8,977,362; 8,993,623; 9,002,458; 9,014,811; 9,015,087; 9,020,576; 9,026,194; 9,026,218; 9,026,372; 9,031,658; 9,034,055; 9,034,923; 9,037,224; 9,042,074; 9,042,201; 9,042,988; 9,044,188; 9,053,516; 9,063,183; 9,064,036; 9,069,031; 9,072,482; 9,074,976; 9,079,940; 9,081,890; 9,095,266; 9,095,303; 9,095,618; 9,101,263; 9,101,276; 9,102,717; 9,113,801; 9,113,803; 9,116,201; 9,125,581; 9,125,788; 9,138,156; 9,142,185; 9,155,373; 9,161,715; 9,167,979; 9,173,609; 9,179,854; 9,179,875; 9,183,351; 9,192,300; 9,198,621; 9,198,707; 9,204,835; 9,211,076; 9,211,077; 9,213,074; 9,229,080; 9,230,539; 9,233,244; 9,238,150; 9,241,665; 9,242,067; 9,247,890; 9,247,911; 9,248,003; 9,248,288; 9,249,200; 9,249,234; 9,251,566; 9,254,097; 9,254,383; 9,259,482; 9,259,591; 9,261,573; 9,265,943; 9,265,965; 9,271,679; 9,280,784; 9,283,279; 9,284,353; 9,285,249; 9,289,595; 9,302,069; 9,309,296; 9,320,900; 9,329,758; 9,331,841; 9,332,939; 9,333,334; 9,336,535; 9,336,611; 9,339,227; 9,345,609; 9,351,651; 9,357,240; 9,357,298; 9,357,970; 9,358,393; 9,359,449; 9,364,462; 9,365,628; 9,367,738; 9,368,018; 9,370,309; 9,370,667; 9,375,573; 9,377,348; 9,377,515; 9,381,352; 9,383,208; 9,392,955; 9,394,347; 9,395,425; 9,396,669; 9,401,033; 9,402,558; 9,403,038; 9,405,366; 9,410,885; 9,411,033; 9,412,233; 9,415,222; 9,418,368; 9,421,373; 9,427,474; 9,438,650; 9,440,070; 9,445,730; 9,446,238; 9,448,289; 9,451,734; 9,451,899; 9,458,208; 9,460,400; 9,462,733; 9,463,327; 9,468,541; 9,471,978; 9,474,852; 9,480,845; 9,480,854; 9,483,117; 9,486,381; 9,486,389; 9,486,618; 9,486,632; 9,492,114; 9,495,684; 9,497,017; 9,498,134; 9,498,634; 9,500,722; 9,505,817; 9,517,031; 9,517,222; 9,519,981; 9,521,958; 9,534,044; 9,538,635; 9,539,118; 9,556,487; 9,558,558; 9,560,458; 9,560,967; 9,560,984; 9,560,986; 9,563,950; 9,568,564; 9,572,996; 9,579,035; 9,579,048; 9,582,925; 9,584,928; 9,588,203; 9,588,490; 9,592,384; 9,600,138; 9,604,073; 9,612,295; 9,618,591; 9,622,660; 9,622,675; 9,630,008; 9,642,553; 9,642,554; 9,643,019; 9,646,248; 9,649,501; 9,655,573; 9,659,186; 9,664,856; 9,665,824; 9,665,987; 9,675,292; 9,681,814; 9,682,232; 9,684,051; 9,685,600; 9,687,562; 9,694,178; 9,694,197; 9,713,428; 9,713,433; 9,713,444; 9,713,712; D627476; RE44097; RE46209; 20010009975; 20020103428; 20020103429; 20020158631; 20020173714; 20030004429; 20030013981; 20030018277; 20030081818; 20030093004; 20030097159; 20030105408; 20030158495; 20030199749; 20040019370; 20040034299; 20040092809; 20040127803; 20040186542; 20040193037; 20040210127; 20040210156; 20040263162; 20050015205; 20050033154; 20050043774; 20050059874; 20050216071; 20050256378; 20050283053; 20060074822; 20060078183; 20060100526; 20060135880; 20060225437; 20070005391; 20070036355; 20070038067; 20070043392; 20070049844; 20070083128; 20070100251; 20070165915; 20070167723; 20070191704; 20070197930; 20070239059; 20080001600; 20080021340; 20080091118; 20080167571; 20080249430; 20080304731; 20090018432; 20090082688; 20090099783; 20090149736; 20090179642; 20090216288; 20090299169; 20090312624; 20090318794; 20090319001; 20090319004; 20100010366; 20100030097; 20100049482; 20100056276; 20100069739; 20100092934; 20100094155; 20100113959; 20100131034; 20100174533; 20100197610; 20100219820; 20110015515; 20110015539; 20110046491; 20110082360; 20110110868; 20110150253; 20110182501; 20110217240; 20110218453; 20110270074; 20110301448; 20120021394; 20120143104; 20120150262; 20120191542; 20120232376; 20120249274; 20120253168; 20120271148; 20130012804; 20130013667; 20130066394; 20130072780; 20130096453; 20130150702; 20130165766; 20130211238; 20130245424; 20130251641; 20130255586; 20130304472; 20140005518; 20140058241; 20140062472; 20140077612; 20140101084; 20140121565; 20140135873; 20140142448; 20140155730; 20140159862; 20140206981; 20140243647; 20140243652; 20140245191; 20140249445; 20140249447; 20140271483; 20140275891; 20140276013; 20140276014; 20140276187; 20140276702; 20140277582; 20140279746; 20140296733; 20140297397; 20140300532; 20140303424; 20140303425; 20140303511; 20140316248; 20140323899; 20140328487; 20140330093; 20140330394; 20140330580; 20140335489; 20140336489; 20140336547; 20140343397; 20140343882; 20140348183; 20140350380; 20140354278; 20140357507; 20140357932; 20140357935; 20140358067; 20140364721; 20140370479; 20140371573; 20140371611; 20140378815; 20140378830; 20150005840; 20150005841; 20150008916; 20150011877; 20150017115; 20150018665; 20150018702; 20150018705; 20150018706; 20150019266; 20150025422; 20150025917; 20150026446; 20150030220; 20150033363; 20150044138; 20150065838; 20150065845; 20150069846; 20150072394; 20150073237; 20150073249; 20150080695; 20150080703; 20150080753; 20150080985; 20150088024; 20150088224; 20150091730; 20150091791; 20150096564; 20150099962; 20150105844; 20150112403; 20150119658; 20150119689; 20150119698; 20150119745; 20150123653; 20150133811; 20150133812; 20150133830; 20150140528; 20150141529; 20150141773; 20150148619; 20150150473; 20150150475; 20150151142; 20150154721; 20150154764; 20150157271; 20150161738; 20150174403; 20150174418; 20150178631; 20150178978; 20150182417; 20150186923; 20150192532; 20150196800; 20150201879; 20150202330; 20150206051; 20150206174; 20150212168; 20150213012; 20150213019; 20150213020; 20150215412; 20150216762; 20150219729; 20150219732; 20150220830; 20150223721; 20150226813; 20150227702; 20150230719; 20150230744; 20150231330; 20150231395; 20150231405; 20150238104; 20150248615; 20150253391; 20150257700; 20150264492; 20150272461; 20150272465; 20150283393; 20150289813; 20150289929; 20150293004; 20150294074; 20150297108; 20150297139; 20150297444; 20150297719; 20150304048; 20150305799; 20150305800; 20150305801; 20150306057; 20150306390; 20150309582; 20150313496; 20150313971; 20150315554; 20150317447; 20150320591; 20150324544; 20150324692; 20150327813; 20150328330; 20150335281; 20150335294; 20150335876; 20150335877; 20150343242; 20150359431; 20150360039; 20150366503; 20150370325; 20150374250; 20160000383; 20160005235; 20160008489; 20160008598; 20160008620; 20160008632; 20160012011; 20160012583; 20160015673; 20160019434; 20160019693; 20160022165; 20160022168; 20160022207; 20160022981; 20160023016; 20160029958; 20160029959; 20160029998; 20160030666; 20160030834; 20160038049; 20160038559; 20160038770; 20160048659; 20160048948; 20160048965; 20160051161; 20160051162; 20160055236; 20160058322; 20160063207; 20160063883; 20160066838; 20160070436; 20160073916; 20160073947; 20160081577; 20160081793; 20160082180; 20160082319; 20160084925; 20160086622; 20160095838; 20160097824; 20160100769; 20160103487; 20160103963; 20160109851; 20160113587; 20160116472; 20160116553; 20160120432; 20160120436; 20160120480; 20160121074; 20160128589; 20160128632; 20160129249; 20160131723; 20160135748; 20160139215; 20160140975; 20160143540; 20160143541; 20160148077; 20160148400; 20160151628; 20160157742; 20160157777; 20160157828; 20160158553; 20160162652; 20160164813; 20160166207; 20160166219; 20160168137; 20160170996; 20160170998; 20160171514; 20160174862; 20160174867; 20160175557; 20160175607; 20160184599; 20160198968; 20160203726; 20160204937; 20160205450; 20160206581; 20160206871; 20160206877; 20160210872; 20160213276; 20160219345; 20160220163; 20160220821; 20160222073; 20160223622; 20160223627; 20160224803; 20160235324; 20160238673; 20160239966; 20160239968; 20160240212; 20160240765; 20160242665; 20160242670; 20160250473; 20160256130; 20160257957; 20160262680; 20160275536; 20160278653; 20160278662; 20160278687; 20160278736; 20160279267; 20160287117; 20160287308; 20160287334; 20160287895; 20160299568; 20160300252; 20160300352; 20160302711; 20160302720; 20160303396; 20160303402; 20160306844; 20160313408; 20160313417; 20160313418; 20160321742; 20160324677; 20160324942; 20160334475; 20160338608; 20160339300; 20160346530; 20160357003; 20160360970; 20160361532; 20160361534; 20160371387; 20170000422; 20170014080; 20170020454; 20170021158; 20170021161; 20170027517; 20170032527; 20170039591; 20170039706; 20170041699; 20170042474; 20170042476; 20170042827; 20170043166; 20170043167; 20170045601; 20170052170; 20170053082; 20170053088; 20170053461; 20170053665; 20170056363; 20170056467; 20170056655; 20170065199; 20170065349; 20170065379; 20170065816; 20170066806; 20170079538; 20170079543; 20170080050; 20170080256; 20170085547; 20170085855; 20170086729; 20170087367; 20170091418; 20170095174; 20170100051; 20170105647; 20170107575; 20170108926; 20170119270; 20170119271; 20170120043; 20170131293; 20170133576; 20170133577; 20170135640; 20170140124; 20170143986; 20170146615; 20170146801; 20170147578; 20170148213; 20170148592; 20170150925; 20170151435; 20170151436; 20170154167; 20170156674; 20170165481; 20170168121; 20170168568; 20170172446; 20170173391; 20170178001; 20170178340; 20170180558; 20170181252; 20170182176; 20170188932; 20170189691; 20170190765; 20170196519; 20170197081; 20170198017; 20170199251; 20170202476; 20170202518; 20170206654; 20170209044; 20170209062; 20170209225; 20170209389; and 20170212188.

Brain entrainment Brain entrainment, also referred to as brainwave synchronization and neural entrainment refers to the capacity of the brain to naturally synchronize its brainwave frequencies with the rhythm of periodic external stimuli, most commonly auditory, visual, or tactile. Brainwave entrainment technologies are used to induce various brain states, such as relaxation or sleep, by creating stimuli that occur at regular, periodic intervals to mimic electrical cycles of the brain during the desired states, thereby “training” the brain to consciously alter states. Recurrent acoustic frequencies, flickering lights, or tactile vibrations are the most common examples of stimuli applied to generate different sensory responses. It is hypothesized that listening to these beats of certain frequencies one can induce a desired state of consciousness that corresponds with specific neural activity. Patterns of neural firing, measured in Hz, correspond with alertness states such as focused attention, deep sleep, etc.

The term “entrainment” has been used to describe a shared tendency of many physical and biological systems to synchronize their periodicity and rhythm through interaction. This tendency has been identified as specifically pertinent to the study of sound and music generally, and acoustic rhythms specifically. The most ubiquitous and familiar examples of neuromotor entrainment to acoustic stimuli is observable in spontaneous foot or finger tapping to the rhythmic beat of a song. Exogenous rhythmic entrainment which occurs outside the body, has been identified and documented for a variety of human activities, which include the way people adjust the rhythm of their speech patterns to those of the subject with whom they communicate, and the rhythmic unison of an audience clapping. Even among groups of strangers, the rate of breathing, locomotive and subtle expressive motor movements, and rhythmic speech patterns have been observed to synchronize and entrain, in response to an auditory stimulus, such as a piece of music with a consistent rhythm. Furthermore, motor synchronization to repetitive tactile stimuli occurs in animals, including cats and monkeys as well as humans, with accompanying shifts in electroencephalogram (EEG) readings. Examples of endogenous entrainment which occurs within the body, include the synchronizing of human circadian sleep-wake cycles to the 24-hour cycle of light and dark, and the frequency following response of humans to sounds and music.

Neural oscillations Neural oscillations are rhythmic or repetitive electrochemical activity in the brain and central nervous system. Such oscillations can be characterized by their frequency, amplitude and phase. Neural tissue can generate oscillatory activity driven by mechanisms within individual neurons, as well as by interactions between them. They may also adjust frequency to synchronize with the periodic vibration of external acoustic or visual stimuli. The functional role of neural oscillations is still not fully understood; however, they have been shown to correlate with emotional responses, motor control, and a number of cognitive functions including information transfer, perception, and memory. Specifically, neural oscillations, in particular theta activity, are extensively linked to memory function, and coupling between theta and gamma activity is considered to be vital for memory functions, including episodic memory. Electroencephalography (EEG) has been most widely used in the study of neural activity generated by large groups of neurons, known as neural ensembles, including investigations of the changes that occur in electroencephalographic profiles during cycles of sleep and wakefulness. EEG signals change dramatically during sleep and show a transition from faster frequencies to increasingly slower frequencies, indicating a relationship between the frequency of neural oscillations and cognitive states including awareness and consciousness.

Brainwaves, or neural oscillations, share the fundamental constituents with acoustic and optical waves, including frequency, amplitude and periodicity. The synchronous electrical activity of cortical neural ensembles can synchronize in response to external acoustic or optical stimuli and also entrain or synchronize their frequency and phase to that of a specific stimulus. Brainwave entrainment is a colloquialism for such ‘neural entrainment’, which is a term used to denote the way in which the aggregate frequency of oscillations produced by the synchronous electrical activity in ensembles of cortical neurons can adjust to synchronize with the periodic vibration of an external stimuli, such as a sustained acoustic frequency perceived as pitch, a regularly repeating pattern of intermittent sounds, perceived as rhythm, a of a regularly rhythmically intermittent flashing light.

Changes in neural oscillations, demonstrable through electroencephalogram (EEG) measurements, are precipitated by listening to music, which can modulate autonomic arousal ergotropically and trophotropically, increasing and decreasing arousal respectively. Musical auditory stimulation has also been demonstrated to improve immune function, facilitate relaxation, improve mood, and contribute to the alleviation of stress.

The Frequency following response (FFR), also referred to as Frequency Following Potential (FFP), is a specific response to hearing sound and music, by which neural oscillations adjust their frequency to match the rhythm of auditory stimuli. The use of sound with intent to influence cortical brainwave frequency is called auditory driving, by which frequency of neural oscillation is ‘driven’ to entrain with that of the rhythm of a sound source.

See, en.wikipedia.org/wiki/Brainwave_entrainment;

U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 5,070,399; 5,306,228; 5,409,445; 6,656,137; 7,749,155; 7,819,794; 7,988,613; 8,088,057; 8,167,784; 8,213,670; 8,267,851; 8,298,078; 8,517,909; 8,517,912; 8,579,793; 8,579,795; 8,597,171; 8,636,640; 8,638,950; 8,668,496; 8,852,073; 8,932,218; 8,968,176; 9,330,523; 9,357,941; 9,459,597; 9,480,812; 9,563,273; 9,609,453; 9,640,167; 9,707,372; 20050153268; 20050182287; 20060106434; 20060206174; 20060281543; 20070066403; 20080039677; 20080304691; 20100010289; 20100010844; 20100028841; 20100056854; 20100076253; 20100130812; 20100222640; 20100286747; 20100298624; 20110298706; 20110319482; 20120003615; 20120053394; 20120150545; 20130030241; 20130072292; 20130131537; 20130172663; 20130184516; 20130203019; 20130234823; 20130338738; 20140088341; 20140107401; 20140114242; 20140154647; 20140174277; 20140275741; 20140309484; 20140371516; 20150142082; 20150283019; 20150296288; 20150313496; 20150313949; 20160008568; 20160019434; 20160055842; 20160205489; 20160235980; 20160239084; 20160345901; 20170034638; 20170061760; 20170087330; 20170094385; 20170095157; 20170099713; 20170135597; and 20170149945.

Carter, J., and H. Russell. “A pilot investigation of auditory and visual entrainment of brain wave activity in learning disabled boys.” Texas Researcher 4.1 (1993): 65-75;

Casciaro, Francesco, et al. “Alpha-rhythm stimulation using brain entrainment enhances heart rate variability in subjects with reduced HRV.” World J. Neuroscience 3.04 (2013): 213;

Helfrich, Randolph F., et al. “Entrainment of brain oscillations by transcranial alternating current stimulation.” Current Biology 24.3 (2014): 333-339;

Huang, Tina L, and Christine Charyton. “A comprehensive review of the psychological effects of brainwave entrainment” Alternative therapies in health and medicine 14.5 (2008): 38;

Joyce, Michael, and Dave Siever. “Audio-visual entrainment program as a treatment for behavior disorders in a school setting.” J. Neurotherapy 4.2 (2000): 9-25;

Keitel, Christian, Cliodhna Quigley, and Philipp Ruhnau. “Stimulus-driven brain oscillations in the alpha range: entrainment of intrinsic rhythms or frequency-following response?” J. Neuroscience 34.31 (2014): 10137-10140;

Lakatos, Peter, et al. “Entrainment of neuronal oscillations as a mechanism of attentional selection.” Science 320.5872 (2008): 110-113;

Mori, Toshio, and Shoichi Kai. “Noise-induced entrainment and stochastic resonance in human brainwaves.” Physical review letters 88.21 (2002): 218101;

Padmanabhan, R., A. J. Hildreth, and D. Laws. “A prospective, randomised, controlled study examining binaural beat audio and pre-operative anxiety in patients undergoing general anaesthesia for day case surgery.” Anaesthesia 60.9 (2005): 874-877;

Schalles, Matt D., and Jaime A. Pineda “Musical sequence learning and EEG correlates of audiomotor processing.” Behavioural neurology 2015 (2015). www.hindawi.com/journals/bn/2015/638202/

Thaut, Michael H., David A. Peterson, and Gerald C. McIntosh. “Temporal entrainment of cognitive functions.” Annals of the New York Academy of Sciences 1060.1 (2005): 243-254.

Thut Gregor, Philippe G. Schyns, and Joachim Gross. “Entrainment of perceptually relevant brain oscillations by non-invasive rhythmic stimulation of the human brain.” Frontiers in Psychology 2 (2011);

Trost, Wiebke, et al. “Getting the beat: entrainment of brain activity by musical rhythm and pleasantness.” NeuroImage 103 (2014): 55-64;

Will, Udo, and Eric Berg. “Brain wave synchronization and entrainment to periodic acoustic stimuli.” Neuroscience letters 424.1 (2007): 55-60; and

Zhuang, Tianbao, Hong Zhao, and Zheng Tang. “A study of brainwave entrainment based on EEG brain dynamics.” Computer and information science 2.2 (2009): 80.

A baseline correction of event-related time-frequency measure may be made to take pre-event baseline activity into consideration. In general, a baseline period is defined by the average of the values within a time window preceding the time-locking event. There are at least four common methods for baseline correction in time-frequency analysis. The methods include various baseline value normalizations. See,

Spencer K M, Nestor P G, Perlmutter R, et al. Neural synchrony indexes disordered perception and cognition in schizophrenia. Proc Natl Acad Sci USA 2004; 101:17288-17293;

Hoogenboom N, Schoffelen J M, Oostenveld R, Parkes L M, Fries P. Localizing human visual gamma-band activity in frequency, time and space. Neuroimage. 2006; 29:764-773;

Le Van Quyen M, Foucher J, Lachaux J, et al. Comparison of Hilbert transform and wavelet methods for the analysis of neuronal synchrony. J Neurosci Methods. 2001; 111:83-98,

Lachaux J P, Rodriguez E, Martinerie J, Varela F J. Measuring phase synchrony in brain signals. Hum Brain Mapp. 1999; 8:194-208,

Rodriguez E, George N, Lachaux J P, Martinerie J, Renault B, Varela F J. Perception's shadow long-distance synchronization of human brain activity. Nature. 1999; 397:430-433.,

Canolty R T, Edwards E, Dalai S S, et al. High gamma power is phase-locked to theta oscillations in human neocortex Science. 2006; 313:1626-1628.

The question of whether different emotional states are associated with specific patterns of physiological response has long being a subject of neuroscience research See, for example:

James W (1884.) What is an emotion? Mind 9: 188-205; Lacey J I, Bateman D E, Vanlehn R (1953) Autonomic response specificity; an experimental study. Psychosom Med 15: 8-21;

Levenson R W, Heider K, Ekman P, Friesen W V (1992) Emotion and Autonomic Nervous-System Activity in the Minangkabau of West Sumatra. J Pers Soc Psychol 62: 972-988.

Some studies have indicated that the physiological correlates of emotions are likely to be found in the central nervous system (CNS). See, for example:

Buck R (1999) The biological affects: A typology. Psychological Review 106: 301-336; Izard C E (2007) Basic Emotions, Natural Kinds, Emotion Schemas, and a New Paradigm. Perspect Psychol Sci 2: 260-280;

Panksepp J (2007) Neurologizing the Psychology of Affects How Appraisal-Based Constructivism and Basic Emotion Theory Can Coexist Perspect Psychol Sci 2: 281-296.

Electroencephalograms (EEG) and functional Magnetic Resonance Imaging, fMRI have been used to study specific brain activity associated with different emotional states. Mauss and Robinson, in their review paper, have indicated that “emotional state is likely to involve circuits rather than any brain region considered in isolation” (Mauss I B, Robinson M D (2009) Measures of emotion: A review. Cogn Emot 23: 209-237.)

The amplitude, latency from the stimulus, and covariance (in the case of multiple electrode sites) of each component can be examined in connection with a cognitive task (ERP) or with no task (EP). Steady-state visually evoked potentials (SSVEPs) use a continuous sinusoidally-modulated flickering light typically superimposed in front of a TV monitor displaying a cognitive task. The brain response in a narrow frequency band containing the stimulus frequency is measured. Magnitude, phase, and coherence (in the case of multiple electrode sites) may be related to different parts of the cognitive task. Brain entrainment may be detected through EEG or MEG activity.

Brain entrainment may be detected through EEG or MEG activity. See:

Abeln, Vera, et al. “Brainwave entrainment for better sleep and post-sleep state of young elite soccer players—A pilot study.” European J. Sport science 14.5 (2014): 393-402;

Acton, George. “Methods for independent entrainment of visual field zones.” U.S. Pat. No. 9,629,976. 25 Apr. 2017;

Albouy, Philippe, et al. “Selective entrainment of theta oscillations in the dorsal stream causally enhances auditory working memory performance.” Neuron 94.1 (2017): 193-206.

Amengual, J., et al. “P018 Local entrainment and distribution across cerebral networks of natural oscillations elicited in implanted epilepsy patients by intracranial stimulation: Paving the way to develop causal connectomics of the healthy human brain.” Clin. Neurophysiology 128.3 (2017): e18;

Argento, Emanuele, et al. “Augmented Cognition via Brainwave Entrainment in Virtual Reality: An Open, Integrated Brain Augmentation in a Neuroscience System Approach.” Augmented Human Research 2.1 (2017): 3;

Bello, Nicholas P. “Altering Cognitive and Brain States Through Cortical Entrainment” (2014); Costa-Faidella, Jordi, Elyse S. Sussman, and Carles Escera. “Selective entrainment of brain oscillations drives auditory perceptual organization.” NeuroImage (2017);

Börgers, Christoph. “Entrainment by Excitatory Input Pulses.” An Introduction to Modeling Neuronal Dynamics. Springer International Publishing, 2017.183-192;

Calderone, Daniel J., et al. “Entrainment of neural oscillations as a modifiable substrate of attention.” Trends in cognitive sciences 18.6 (2014): 300-309;

Casciaro, Francesco, et al. “Alpha-rhythm stimulation using brain entrainment enhances heart rate variability in subjects with reduced HRV.” World J. Neuroscience 3.04 (2013): 213;

Chang, Daniel Wonchul. “Method and system for brain entertainment” U.S. Pat. No. 8,636,640. 28 Jan. 2014;

Colzato, Lorenza S., Amengual, Julià L, et al. “Local entrainment of oscillatory activity induced by direct brain stimulation in humans.” Scientific Reports 7 (2017);

Conte, Elio, et al. “A Fast Fourier Transform analysis of time series data of heart rate variability during alfa-rhythm stimulation in brain entrainment” NeuroQuantology 11.3 (2013);

Dikker, Suzanne, et al. “Brain-to-brain synchrony tracks real-world dynamic group interactions in the classroom.” Current Biology 27.9 (2017): 1375-1380;

Ding, Nai, and Jonathan Z Simon. “Cortical entrainment to continuous speech: functional roles and interpretations.” Frontiers in human neuroscience 8 (2014);

Doherty, Cormac. “A comparison of alpha brainwave entrainment with and without musical accompaniment” (2014);

Falk, Simone, Cosima Lanzilotti, and Daniele Schön. “Tuning neural phase entrainment to speech.” J. Cognitive Neuroscience (2017);

Gao, Junling, et al. “Entrainment of chaotic activities in brain and heart during MBSR mindfulness training.” Neuroscience letters 616 (2016): 218-223;

Gooding-Williams, Gerard, Hongfang Wang, and Klaus Kessler. “THETA-Rhythm Makes the World Go Round: Dissociative Effects of TMS Theta Versus Alpha Entrainment of Right pTPJ on Embodied Perspective Transformations.” Brain Topography (2017): 1-4;

Hanslmayr, Simon, Jonas Matuschek, and Marie-Christin Fellner. “Entrainment of prefrontal beta oscillations induces an endogenous echo and impairs memory formation.” Current Biology 24.8 (2014): 904-909;

Heideman, Simone G., Erik S. te Woerd, and Peter Praamstra “Rhythmic entrainment of slow brain activity preceding leg movements.” Clin. Neurophysiology 126.2 (2015): 348-355;

Helfrich, Randolph F., et al. “Entrainment of brain oscillations by transcranial alternating current stimulation.” Current Biology 24.3 (2014): 333-339;

Henry, Molly J., et al. “Aging affects the balance of neural entrainment and top-down neural modulation in the listening brain.” Nature Communications 8 (2017): ncomms15801;

Horr, Ninja K., Maria Wimber, and Massimiliano Di Luca “Perceived time and temporal structure: Neural entrainment to isochronous stimulation increases duration estimates.” Neuroimage 132 (2016): 148-156;

Irwin, Rosie. “Entraining Brain Oscillations to Influence Facial Perception.” (2015);

Kalyan, Ritu, and Bipan Kaushal. “Binaural Entrainment and Its Effects on Memory.” (2016);

Keitel, Anne, et al. “Auditory cortical delta-entrainment interacts with oscillatory power in multiple fronto-parietal networks.” Neuroimage 147 (2017): 32-42;

Keitel, Christian, Cliodhna Quigley, and Philipp Ruhnau. “Stimulus-driven brain oscillations in the alpha range: entrainment of intrinsic rhythms or frequency-following response?” J. Neuroscience 34.31 (2014): 10137-10140;

Koelsch, Stefan. “Music-evoked emotions: principles, brain correlates, and implications for therapy.” Annals of the New York Academy of Sciences 1337.1 (2015): 193-201;

Kösem, Anne, et al. “Neural entrainment reflects temporal predictions guiding speech comprehension.” the Eighth Annual Meeting of the Society for the Neurobiology of Language (SNL 2016). 2016;

Lee, Daniel Keewoong, Dongyeup Daniel Synn, and Daniel Chesong Lee. “Intelligent earplug system.” U.S. patent application Ser. No. 15/106,989;

Lefoumour, Joseph, Ramaswamy Palaniappan, and Ian V. McLoughlin. “Inter-hemispheric and spectral power analyses of binaural beat effects on the brain.” Matters 2.9 (2016): e201607000001;

Mai, Guangting, James W. Minett, and William S-Y. Wang. “Delta, theta, beta, and gamma brain oscillations index levels of auditory sentence processing.” Neuroimage 133(2016):516-528;

Marconi, Pier Luigi, et al. “The phase amplitude coupling to assess brain network system integration.” Medical Measurements and Applications (MeMeA), 2016 IEEE International Symposium on. IEEE, 2016;

McLaren, Elgin-Skye, and Alissa N. Antle. “Exploring and Evaluating Sound for Helping Children Self-Regulate with a Brain-Computer Application.” Proceedings of the 2017 Conference on Interaction Design and Children. ACM, 2017;

Moisa, Marius, et al. “Brain network mechanisms underlying motor enhancement by transcranial entrainment of gamma oscillations.” J. Neuroscience 36.47 (2016): 12053-12065;

Molinaro, Nicola, et al. “Out-of-synchrony speech entrainment in developmental dyslexia” Human brain mapping 37.8 (2016): 2767-2783;

Moseley, Ralph. “Immersive brain entrainment in virtual worlds: actualizing meditative states.” Emerging Trends and Advanced Technologies for Computational Intelligence. Springer International Publishing, 2016. 315-346;

Neuling, Toralf, et al. “Friends, not foes: magnetoencephalography as a tool to uncover brain dynamics during transcranial alternating current stimulation.” Neuroimage 118 (2015): 406-413;

Notbohm, Annika, Jürgen Kurths, and Christoph S. Herrmann. “Modification of brain oscillations via rhythmic light stimulation provides evidence for entrainment but not for superposition of event-related responses.” Frontiers in human neuroscience 10 (2016);

Nozaradan, S., et al. “P943: Neural entrainment to musical rhythms in the human auditory cortex, as revealed by intracerebral recordings.” Clin. Neurophysiology 125 (2014): S299;

Palaniappan, Ramaswamy, et al. “Improving the feature stability and classification performance of bimodal brain and heart biometrics.” Advances in Signal Processing and Intelligent Recognition Systems. Springer, Cham, 2016. 175-186;

Palaniappan, Ramaswamy, Somnuk Phon-Amnuaisuk, and Chikkannan Eswaran. “On the binaural brain entrainment indicating lower heart rate variability.” Int. J. Cardiol 190 (2015): 262-263;

Papagiannakis, G., et al. A virtual reality brainwave entrainment method for human augmentation applications. Technical Report FORTH-ICS/TR458, 2015;

Park, Hyojin, et al. “Frontal top-down signals increase coupling of auditory low-frequency oscillations to continuous speech in human listeners.” Current Biology 25.12 (2015): 1649-1653;

Pérez, Alqandro, Manuel Carreiras, and Jon Andoni Duñabeitia. “Brain-to-brain entrainment EEG interbrain synchronization while speaking and listening.” Scientific Reports 7 (2017);

Riecke, Lars, Alexander T. Sack, and Charles E. Schroeder. “Endogenous delta/theta sound-brain phase entrainment accelerates the buildup of auditory streaming.” Current Biology 25.24 (2015): 3196-3201;

Spaak, Eelke, Floris P. de Lange, and Ole Jensen, “Local entrainment of alpha oscillations by visual stimuli causes cyclic modulation of perception.” J. Neuroscience 34.10(2014):3536-3544;

Thaut, Michael H. “The discovery of human auditory-motor entrainment and its role in the development of neurologic music therapy.” Progress in brain research 217 (2015): 253-266;

Thaut, Michael H., Gerald C. Mcintosh, and Volker Hoemberg. “Neurobiological foundations of neurologic music therapy: rhythmic entrainment and the motor system.” Frontiers in psychology 5 (2014);

Thut, G. “T030 Guiding TMS by EEG/MEG to interact with oscillatory brain activity and associated functions.” Clin. Neurophysiology 128.3 (2017): e9;

Treviño, Guadalupe Villarreal, et al. “The Effect of Audio Visual Entrainment on Pre-Attentive Dysfunctional Processing to Stressful Events in Anxious Individuals.” Open J. Medical Psychology 3.05 (2014): 364;

Trost Wiebke, et al. “Getting the beat entrainment of brain activity by musical rhythm and pleasantness.” NeuroImage 103 (2014): 55-64;

Tsai, Shu-Hui, and Yue-DerLin. “Autonomie feedback with brain entrainment” Awareness Science and Technology and Ubi-Media Computing (iCAST-UMEDIA), 2013 International Joint Conference on. IEEE, 2013;

Vossen, Alexandra, Joachim Gross, and Gregor Thut. “Alpha power increase after transcranial alternating current stimulation at alpha frequency (α-tACS) reflects plastic changes rather than entrainment” Brain Stimulation 8.3 (2015): 499-508;

Witkowski, Matthias, et al. “Mapping entrained brain oscillations during transcranial alternating current stimulation (tACS).” Neuroimage 140 (2016): 89-98;

Zlotnik, Anatoly, Raphad Nagao, and István Z. Kiss Jr-Shin Li. “Phase-selective entrainment of nonlinear oscillator ensembles.” Nature Communications 7 (2016).

The entrainment hypothesis (Thut and Miniussi, 2009; Thut et al., 2011a, 2012), suggests the possibility of inducing a particular oscillation frequency in the brain using an external oscillatory force (e.g., rTMS, but also tACS). The physiological basis of oscillatory cortical activity lies in the timing of the interacting neurons; when groups of neurons synchronize their firing activities, brain rhythms emerge, network oscillations are generated, and the basis for interactions between brain areas may develop (Buzsàki, 2006). Because of the variety of experimental protocols for brain stimulation, limits on descriptions of the actual protocols employed, and limited controls, consistency of reported studies is lacking, and extrapolability is limited. Thus, while there is various consensus in various aspects of the effects of extra cranial brain stimulation, the results achieved have a degree of uncertainty dependent on details of implementation. On the other hand, within a specific experimental protocol, it is possible to obtain statistically significant and repeatable results. This implies that feedback control might be effective to control implementation of the stimulation for a given purpose; however, studies that employ feedback control are lacking.

Different cognitive states are associated with different oscillatory patterns in the brain (Buzsaki, 2006; Canolty and Knight, 2010; Varela et al., 2001). Thut et al. (2011b) directly tested the entrainment hypothesis by means of a concurrent EEG-TMS experiment. They first determined the individual source of the parietal-occipital alpha modulation and the individual alpha frequency (magnetoencephalography study). They then applied rTMS at the individual alpha power while recording the EEG activity at rest. The results confirmed the three predictions of the entrainment hypothesis: the induction of a specific frequency after TMS, the enhancement of oscillation during TMS stimulation due to synchronization, and a phase alignment of the induced frequency and the ongoing activity (Thut et al., 2011b).

If associative stimulation is a general principle for human neural plasticity in which the timing and strength of activation are critical factors, it is possible that synchronization within or between areas using an external force to phase/align oscillations can also favor efficient communication and associative plasticity (or alter communication). In this respect associative, cortico-cortical stimulation has been shown to enhance coherence of oscillatory activity between the stimulated areas (Plewnia et al., 2008).

In coherence resonance (Longtin, 1997), the addition of a certain amount of noise in an excitable system results in the most coherent and proficient oscillatory responses. The brain's response to external timing-embedded stimulation can result in a decrease in phase variance and an enhanced alignment (clustering) of the phase components of the ongoing EEG activity (entraining, phase resetting) that can change the signal-to-noise ratio and increase (or decrease) signal efficacy.

If one considers neuron activity within the brain as a set of loosely coupled oscillators, then the various parameters that might be controlled include the size of the region of neurons, frequency of oscillation, resonant frequency or time-constant, oscillator damping, noise, amplitude, coupling to other oscillators, and of course, external influences that may include stimulation and/or power loss. In a human brain, pharmacological intervention may be significant. For example, drugs that alter excitability, such as caffeine, neurotransmitter release and reuptake, nerve conductance, etc. can all influence operation of the neural oscillators. Likewise, subthreshold external stimulation effects, including DC, AC and magnetic electromagnetic effects, can also influence operation of the neural oscillators.

Phase resetting or shifting can synchronize inputs and favor communication and, eventually, Hebbian plasticity (Hebb, 1949). Thus, rhythmic stimulation may induce a statistically higher degree of coherence in spiking neurons, which facilitates the induction of a specific cognitive process (or hinders that process). Here, the perspective is slightly different (coherence resonance), but the underlining mechanisms are similar to the ones described so far (stochastic resonance), and the additional key factor is the repetition at a specific rhythm of the stimulation.

In the 1970+s, the British biophysicist and psychobiologist C. Maxwell Cade, monitored the brainwave patterns of advanced meditators and 300 of his students. Here he found that the most advanced meditators have a specific brainwave pattern that was different from the rest of his students. He noted that these meditators showed high activity of alpha brainwaves accompanied by beta, theta and even delta waves that were about half the amplitude of the alpha waves. See, Cade “The Awakened Mind: Biofeedback and the Development of Higher States of Awareness” (Dell, 1979). Anna Wise extended Cade's studies, and found that extraordinary achievers which included composers, inventors, artists, athletes, dancers, scientists, mathematicians, CEO's and presidents of large corporations have brainwave patterns differ from average performers, with a specific balance between Beta, Alpha, Theta and Delta brainwaves where Alpha had the strongest amplitude. See, Anna Wise, “The High-Performance Mind: Mastering Brainwaves for Insight Healing, and Creativity”.

Entrainment is plausible because of the characteristics of the demonstrated EEG responses to a single TMS pulse, which have a spectral composition which resemble the spontaneous oscillations of the stimulated cortex. For example, TMS of the “resting” visual (Rosanova et al., 2009) or motor cortices (Veniero et al., 2011) triggers alpha-waves, the natural frequency at the resting state of both types of cortices. With the entrainment hypothesis, the noise generation framework moves to a more complex and extended level in which noise is synchronized with on-going activity. Nevertheless, the model to explain the outcome will not change, stimulation will interact with the system, and the final result will depend on introducing or modifying the noise level. The entrainment hypothesis makes clear predictions with respect to online repetitive TMS paradigms' frequency engagement as well as the possibility of inducing phase alignment i.e., a reset of ongoing brain oscillations via external sp TMS (Thut et al., 2011a, 2012; Veniero et al., 2011). The entrainment hypothesis is superior to the localization approach in gaining knowledge about how the brain works, rather than where or when a single process occurs. TMS pulses may phase-align the natural, ongoing oscillation of the target cortex. When additional TMS pulses are delivered in synchrony with the phase-aligned oscillation (i.e., at the same frequency), further synchronized phase-alignment will occur, which will bring the oscillation of the target area in resonance with the TMS train. Thus, entrainment may be expected when TMS is frequency-tuned to the underlying brain oscillations (Veniero et al., 2011).

Binaural Beats Binaural beats are auditory brainstem responses which originate in the superior olivary nucleus of each hemisphere. They result from the interaction of two different auditory impulses, originating in opposite ears, below 1000 Hz and which differ in frequency between one and 30 Hz For example, if a pure tone of 400 Hz is presented to the right ear and a pure tone of 410 Hz is presented simultaneously to the left ear, an amplitude modulated standing wave of 10 Hz, the difference between the two tones, is experienced as the two wave forms mesh in and out of phase within the superior olivary nuclei. This binaural beat is not heard in the ordinary sense of the word (the human range of hearing is from 20-20,000 Hz). It is perceived as an auditory beat and theoretically can be used to entrain specific neural rhythms through the frequency-following response (FFR)—the tendency for cortical potentials to entrain to or resonate at the frequency of an external stimulus. Thus, it is theoretically possible to utilize a specific binaural-beat frequency as a consciousness management technique to entrain a specific cortical rhythm. The binaural-beat appears to be associated with an electroencephalographic (EEG) frequency-following response in the brain.

Uses of audio with embedded binaural beats that are mixed with music or various pink a background sound are diverse. They range from relaxation, meditation, stress reduction, pain management improved sleep quality, decrease in sleep requirements, super learning, enhanced creativity and intuition, remote viewing, telepathy, and out-of-body experience and lucid dreaming. Audio embedded with binaural beats is often combined with various meditation techniques, as well as positive affirmations and visualization.

When signals of two different frequencies are presented, one to each ear, the brain detects phase differences between these signals. “Under natural circumstances a detected phase difference would provide directional information. The brain processes this anomalous information differently when these phase differences are heard with stereo headphones or speakers. A perceptual integration of the two signals takes place, producing the sensation of a third “beat” frequency. The difference between the signals waxes and wanes as the two different input frequencies mesh in and out of phase. As a result of these constantly increasing and decreasing differences, an amplitude-modulated standing wave—the binaural beat—is heard. The binaural beat is perceived as a fluctuating rhythm at the frequency of the difference between the two auditory inputs. Evidence suggests that the binaural beats are generated in the brainstem's superior olivary nucleus, the first site of contralateral integration in the auditory system. Studies also suggest that the frequency-following response originates from the inferior colliculus. This activity is conducted to the cortex where it can be recorded by scalp electrodes. Binaural beats can easily be heard at the low frequencies (<30 Hz) that are characteristic of the EEG spectrum.

Synchronized brainwaves have long been associated with meditative and hypnogogic states, and audio with embedded binaural beats has the ability to induce and improve such states of consciousness. The reason for this is physiological. Each ear is “hardwired” (so to speak) to both hemispheres of the brain. Each hemisphere has its own olivary nucleus (sound-processing center) which receives signals from each ear. In keeping with this physiological structure, when a binaural beat is perceived there are actually two standing waves of equal amplitude and frequency present one in each hemisphere. So, there are two separate standing waves entraining portions of each hemisphere to the same frequency. The binaural beats appear to contribute to the hemispheric synchronization evidenced in meditative and hypnogogic states of consciousness. Brain function is also enhanced through the increase of cross-collosal communication between the left and right hemispheres of the brain. en.wikipedia.org/wiki/Beat_(acoustics)#Binaural_beats. See:

Oster, G (October 1973). “Auditory beats in the brain”. Scientific American. 229 (4): 94-102. See:

Lane, J. D., Kasian, S. J., Owens, J. E., & Marsh, G. R. (1998). Binaural auditory beats affect vigilance performance and mood. Physiology & behavior, 63(2), 249-252;

Foster, D. S. (1990). EEG and subjective correlates of alpha frequency binaural beats stimulation combined with alpha biofeedback (Doctoral dissertation, Memphis State University);

Kasprzak, C. (2011). Influence of binaural beats on EEG signal. Acta Physica Polonica A, 119(6A), 986-990;

Pratt, H., Starr, A., Michalewski, H. J., Dimitrijevic, A., Bleich, N., & Mittelman, N. (2009). Cortical evoked potentials to an auditory illusion: binaural beats. Clinical Neurophysiology, 120(8), 1514-1524;

Pratt, H., Starr, A., Michalewski, H. J., Dimitrijevic, A., Bleich, N., & Mittelman, N. (2010). A comparison of auditory evoked potentials to acoustic beats and to binaural beats. Hearing research, 262(1), 3444;

Padmanabhan, R., Hildreth, A. J., & Laws, D. (2005). A prospective, randomised, controlled study examining binaural beat audio and pre-operative anxiety in patients undergoing general anaesthesia for day case surgery. Anaesthesia, 60(9), 874-877;

Reedijk, S. A., Bolders, A., & Hommel, B. (2013). The impact of binaural beats on creativity. Frontiers in human neuroscience, 7;

Atwater, F. H. (2001). Binaural beats and the regulation of arousal levels. Proceedings of the TANS, 11;

Hink, R. F., Kodera, K., Yamada, O., Kaga, K., & Suzuki, J. (1980). Binaural interaction of a beating frequency-following response. Audiology, 19(1), 36-43;

Gao, X, Cao, H., Ming, D., Qi, H., Wang, X, Wang, X, & Zhou, P. (2014). Analysis of EEG activity in response to binaural beats with different frequencies. International Journal of Psychophysiology, 94(3), 399-406;

Sung, H. C., Lee, W. L, Li, H. M., Lin, C. Y., Wu, Y. Z, Wang, J. J., & Li, T. L. (2017). Familiar Music Listening with Binaural Beats for Older People with Depressive Symptoms in Retirement Homes. Neuropsychiatry, 7(4);

Colzato, L. S., Barone, H., Sellaro, R., & Hommel, B. (2017). More attentional focusing through binaural beats: evidence from the global-local task. Psychological research, 81 (1), 271-277;

Mortazavi, S. M. J., Zahraei-Moghadam, S. M., Masoumi, S., Rafati, A., Haghani, M., Mortazavi, S. A. R., & Zehtabian, M. (2017). Short Term Exposure to Binaural Beats Adversely Affects Learning and Memory in Rats. Journal of Biomedical Physics and Engineering.

Brain Entrainment Frequency Following Response (or FFR). See, “Stimulating the Brain with Light and Sound,” Transparent Corporation, Neuroprogrammer™ 3, www.transparentcorp.com/products/np/entrainment.php.

Isochronic Tones Isochronic tones are regular beats of a single tone that are used alongside monaural beats and binaural beats in the process called brainwave entrainment. At its simplest level, an isochronic tone is a tone that is being turned on and off rapidly. They create sharp, distinctive pulses of sound.

www.livingflow.net/isochronic-tones-work/;

Schulze, H. H. (1989). The perception of temporal deviations in isochronic patterns. Attention, Perception, & Psychophysics, 45(4), 291-296;

Oster, G. (1973). Auditory beats in the brain. Scientific American, 229(4), 94-102;

Huang, T. L, & Charyton, C. (2008). A comprehensive review of the psychological effects of brainwave entrainment Alternative therapies in health and medicine, 14(5), 38;

Trost W., Frühholz, S., Schön, D., Lalobé, C., Pichon, S., Grandjean, D., & Vuilleumier, P. (2014). Getting the beat entrainment of brain activity by musical rhythm and pleasantness. NeuroImage, 103, 55-64;

Casciaro, F., Lalerza, V., Conte, S., Pieralice, M., Federici, A., Todarello, O., . . . & Conte, E. (2013). Alpha-rhythm stimulation using brain entrainment enhances heart rate variability in subjects with reduced HRV. World Journal of Neuroscience, 3(04), 213;

Conte, Elio, Sergio Conte, Nunzia Santacroce, Antonio Federici, Orlando Todarello, Franco Orsucci, Francesco Casciaro, and Vincenza Laterza “A Fast Fourier Transform analysis of time series data of heart rate variability during alfa-rhythm stimulation in brain entrainment” NeuroQuantology 11, no. 3 (2013);

Doherty, C. (2014). A comparison of alpha brainwave entrainment, with and without musical accompaniment

Moseley, R. (2015, July). Inducing targeted brain states utilizing merged reality systems. In Science and Information Conference (SAI), 2015 (pp. 657-663). IEEE.

Time-Frequency Analysis Brian J. Roach and Daniel H. Mathalon, “Event-related EEG time-frequency analysis: an overview of measures and analysis of early gamma band phase locking in schizophrenia. Schizophrenia Bull. USA. 2008; 34:5:907-926., describes a mechanism for EEG time-frequency analysis. Fourier and wavelet transforms (and their inverse) may be performed on EEG signals.

See, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 4,407,299; 4,408,616; 4,421,122; 4,493,327; 4,550,736; 4,557,270; 4,579,125; 4,583,190; 4,585,011; 4,610,259; 4,649,482; 4,705,049; 4,736,307; 4,744,029; 4,776,345; 4,792,145; 4,794,533; 4,846,190; 4,862,359; 4,883,067; 4,907,597; 4,924,875; 4,940,058; 5,010,891; 5,020,540; 5,029,082; 5,083,571; 5,092,341; 5,105,354; 5,109,862; 5,218,530; 5,230,344; 5,230,346; 5,233,517; 5,241,967; 5,243,517; 5,269,315; 5,280,791; 5,287,859; 5,309,917; 5,309,923; 5,320,109; 5,339,811; 5,339,826; 5,377,100; 5,406,956; 5,406,957; 5,443,073; 5,447,166; 5,458,117; 5,474,082; 5,555,889; 5,611,350; 5,619,995; 5,632,272; 5,643,325; 5,678,561; 5,685,313; 5,692,517; 5,694,939; 5,699,808; 5,752,521; 5,755,739; 5,771,261; 5,771,897; 5,794,623; 5,795,304; 5,797,840; 5,810,737; 5,813,993; 5,827,195; 5,840,040; 5,846,189; 5,846,208; 5,853,005; 5,871,517; 5,884,626; 5,899,867; 5,916,171; 5,995,868; 6,002,952; 6,011,990; 6,016,444; 6,021,345; 6,032,072; 6,044,292; 6,050,940; 6,052,619; 6,067,462; 6,067,467; 6,070,098; 6,071,246; 6,081,735; 6,097,980; 6,097,981; 6,115,631; 6,117,075; 6,129,681; 6,155,993; 6,157,850; 6,157,857; 6,171,258; 6,195,576; 6,196,972; 6,224,549; 6,236,872; 6,287,328; 6,292,688; 6,293,904; 6,305,943; 6,306,077; 6,309,342; 6,315,736; 6,317,627; 6,325,761; 6,331,164; 6,338,713; 6,343,229; 6,358,201; 6,366,813; 6,370,423; 6,375,614; 6,377,833; 6,385,486; 6,394,963; 6,402,520; 6,475,163; 6,482,165; 6,493,577; 6,496,724; 6,511,424; 6,520,905; 6,520,921; 6,524,249; 6,527,730; 6,529,773; 6,544,170; 6,546,378; 6,547,736; 6,547,746; 6,549,804; 6,556,861; 6,565,518; 6,574,573; 6,594,524; 6,602,202; 6,616,611; 6,622,036; 6,625,485; 6,626,676; 6,650,917; 6,652,470; 6,654,632; 6,658,287; 6,678,548; 6,687,525; 6,699,194; 6,709,399; 6,726,624; 6,731,975; 6,735,467; 6,743,182; 6,745,060; 6,745,156; 6,746,409; 6,751,499; 6,768,920; 6,798,898; 6,801,803; 6,804,661; 6,816,744; 6,819,956; 6,826,426; 6,843,774; 6,865,494; 6,875,174; 6,882,881; 6,886,964; 6,915,241; 6,928,354; 6,931,274; 6,931,275; 6,981,947; 6,985,769; 6,988,056; 6,993,380; 7,011,410; 7,014,613; 7,016,722; 7,037,260; 7,043,293; 7,054,454; 7,089,927; 7,092,748; 7,099,714; 7,104,963; 7,105,824; 7,123,955; 7,128,713; 7,130,691; 7,146,218; 7,150,710; 7,150,715; 7,150,718; 7,163,512; 7,164,941; 7,177,675; 7,190,995; 7,207,948; 7,209,788; 7,215,986; 7,225,013; 7,228,169; 7,228,171; 7,231,245; 7,254,433; 7,254,439; 7,254,500; 7,267,652; 7,269,456; 7,286,871; 7,288,066; 7,297,110; 7,299,088; 7,324,845; 7,328,053; 7,333,619; 7,333,851; 7,343,198; 7,367,949; 7,373,198; 7,376,453; 7,381,185; 7,383,070; 7,392,079; 7,395,292; 7,396,333; 7,399,282; 7,403,814; 7,403,815; 7,418,290; 7,429,247; 7,450,986; 7,454,240; 7,462,151; 7,468,040; 7,469,697; 7,471,971; 7,471,978; 7,489,958; 7,489,964; 7,491,173; 7,496,393; 7,499,741; 7,499,745; 7,509,154; 7,509,161; 7,509,163; 7,510,531; 7,530,955; 7,537,568; 7,539,532; 7,539,533; 7,547,284; 7,558,622; 7,559,903; 7,570,991; 7,572,225; 7,574,007; 7,574,254; 7,593,767; 7,594,122; 7,596,535; 7,603,168; 7,604,603; 7,610,094; 7,623,912; 7,623,928; 7,625,340; 7,630,757; 7,640,055; 7,643,655; 7,647,098; 7,654,948; 7,668,579; 7,668,591; 7,672,717; 7,676,263; 7,678,061; 7,684,856; 7,697,979; 7,702,502; 7,706,871; 7,706,992; 7,711,417; 7,715,910; 7,720,530; 7,727,161; 7,729,753; 7,733,224; 7,734,334; 7,747,325; 7,751,878; 7,754,190; 7,757,690; 7,758,503; 7,764,987; 7,771,364; 7,774,052; 7,774,064; 7,778,693; 7,787,946; 7,794,406; 7,801,592; 7,801,593; 7,803,118; 7,803,119; 7,809,433; 7,811,279; 7,819,812; 7,831,302; 7,853,329; 7,860,561; 7,865,234; 7,865,235; 7,878,965; 7,879,043; 7,887,493; 7,894,890; 7,896,807; 7,899,525; 7,904,144; 7,907,994; 7,909,771; 7,918,779; 7,920,914; 7,930,035; 7,938,782; 7,938,785; 7,941,209; 7,942,824; 7,944,551; 7,962,204; 7,974,696; 7,983,741; 7,983,757; 7,986,991; 7,993,279; 7,996,075; 8,002,553; 8,005,534; 8,005,624; 8,010,347; 8,019,400; 8,019,410; 8,024,032; 8,025,404; 8,032,209; 8,033,996; 8,036,728; 8,036,736; 8,041,136; 8,046,041; 8,046,042; 8,065,011; 8,066,637; 8,066,647; 8,068,904; 8,073,534; 8,075,499; 8,079,953; 8,082,031; 8,086,294; 8,089,283; 8,095,210; 8,103,333; 8,108,036; 8,108,039; 8,114,021; 8,121,673; 8,126,528; 8,128,572; 8,131,354; 8,133,172; 8,137,269; 8,137,270; 8,145,310; 8,152,732; 8,155,736; 8,160,689; 8,172,766; 8,177,726; 8,177,727; 8,180,420; 8,180,601; 8,185,207; 8,187,201; 8,190,227; 8,190,249; 8,190,251; 8,197,395; 8,197,437; 8,200,319; 8,204,583; 8,211,035; 8,214,007; 8,224,433; 8,236,005; 8,239,014; 8,241,213; 8,244,340; 8,244,475; 8,249,698; 8,271,077; 8,280,502; 8,280,503; 8,280,514; 8,285,368; 8,290,575; 8,295,914; 8,296,108; 8,298,140; 8,301,232; 8,301,233; 8,306,610; 8,311,622; 8,314,707; 8,315,970; 8,320,649; 8,323,188; 8,323,189; 8,323,204; 8,328,718; 8,332,017; 8,332,024; 8,335,561; 8,337,404; 8,340,752; 8,340,753; 8,343,026; 8,346,342; 8,346,349; 8,352,023; 8,353,837; 8,354,881; 8,356,594; 8,359,080; 8,364,226; 8,364,254; 8,364,255; 8,369,940; 8,374,690; 8,374,703; 8,380,296; 8,382,667; 8,386,244; 8,391,966; 8,396,546; 8,396,557; 8,401,624; 8,401,626; 8,403,848; 8,425,415; 8,425,583; 8,428,696; 8,437,843; 8,437,844; 8,442,626; 8,449,471; 8,452,544; 8,454,555; 8,461,988; 8,463,007; 8,463,349; 8,463,370; 8,465,408; 8,467,877; 8,473,024; 8,473,044; 8,473,306; 8,475,354; 8,475,368; 8,475,387; 8,478,389; 8,478,394; 8,478,402; 8,480,554; 8,484,270; 8,494,829; 8,498,697; 8,500,282; 8,500,636; 8,509,885; 8,509,904; 8,512,221; 8,512,240; 8,515,535; 8,519,853; 8,521,284; 8,525,673; 8,525,687; 8,527,435; 8,531,291; 8,538,512; 8,538,514; 8,538,705; 8,542,900; 8,543,199; 8,543,219; 8,545,416; 8,545,436; 8,554,311; 8,554,325; 8,560,034; 8,560,073; 8,562,525; 8,562,526; 8,562,527; 8,562,951; 8,568,329; 8,571,642; 8,585,568; 8,588,933; 8,591,419; 8,591,498; 8,597,193; 8,600,502; 8,606,351; 8,606,356; 8,606,360; 8,620,419; 8,628,480; 8,630,699; 8,632,465; 8,632,750; 8,641,632; 8,644,914; 8,644,921; 8,647,278; 8,649,866; 8,652,038; 8,655,817; 8,657,756; 8,660,799; 8,666,467; 8,670,603; 8,672,852; 8,680,991; 8,684,900; 8,684,922; 8,684,926; 8,688,209; 8,690,748; 8,693,756; 8,694,087; 8,694,089; 8,694,107; 8,700,137; 8,700,141; 8,700,142; 8,706,205; 8,706,206; 8,706,207; 8,708,903; 8,712,507; 8,712,513; 8,725,238; 8,725,243; 8,725,311; 8,725,669; 8,727,978; 8,728,001; 8,738,121; 8,744,563; 8,747,313; 8,747,336; 8,750,971; 8,750,974; 8,750,992; 8,755,854; 8,755,856; 8,755,868; 8,755,869; 8,755,871; 8,761,866; 8,761,869; 8,764,651; 8,764,652; 8,764,653; 8,768,447; 8,771,194; 8,775,340; 8,781,193; 8,781,563; 8,781,595; 8,781,597; 8,784,322; 8,786,624; 8,790,255; 8,790,272; 8,792,974; 8,798,735; 8,798,736; 8,801,620; 8,821,408; 8,825,149; 8,825,428; 8,827,917; 8,831,705; 8,838,226; 8,838,227; 8,843,199; 8,843,210; 8,849,390; 8,849,392; 8,849,681; 8,852,100; 8,852,103; 8,855,758; 8,858,440; 8,858,449; 8,862,196; 8,862,210; 8,862,581; 8,868,148; 8,868,163; 8,868,172; 8,868,174; 8,868,175; 8,870,737; 8,880,207; 8,880,576; 8,886,299; 8,888,672; 8,888,673; 8,888,702; 8,888,708; 8,898,037; 8,902,070; 8,903,483; 8,914,100; 8,915,741; 8,915,871; 8,918,162; 8,918,178; 8,922,788; 8,923,958; 8,924,235; 8,932,227; 8,938,301; 8,942,777; 8,948,834; 8,948,860; 8,954,146; 8,958,882; 8,961,386; 8,965,492; 8,968,195; 8,977,362; 8,983,591; 8,983,628; 8,983,629; 8,986,207; 8,989,835; 8,989,836; 8,996,112; 9,008,367; 9,008,754; 9,008,771; 9,014,216; 9,014,453; 9,014,819; 9,015,057; 9,020,576; 9,020,585; 9,020,789; 9,022,936; 9,026,202; 9,028,405; 9,028,412; 9,033,884; 9,037,224; 9,037,225; 9,037,530; 9,042,952; 9,042,958; 9,044,188; 9,055,871; 9,058,473; 9,060,671; 9,060,683; 9,060,695; 9,060,722; 9,060,746; 9,072,482; 9,078,577; 9,084,584; 9,089,310; 9,089,400; 9,095,266; 9,095,268; 9,100,758; 9,107,586; 9,107,595; 9,113,777; 9,113,801; 9,113,830; 9,116,835; 9,119,551; 9,119,583; 9,119,597; 9,119,598; 9,125,574; 9,131,864; 9,135,221; 9,138,183; 9,149,214; 9,149,226; 9,149,255; 9,149,577; 9,155,484; 9,155,487; 9,155,521; 9,165,472; 9,173,582; 9,173,610; 9,179,854; 9,179,876; 9,183,351 RE34015; RE38476; RE38749; RE46189; 20010049480; 20010051774; 20020035338; 20020055675; 20020059159; 20020077536; 20020082513; 20020085174; 20020091319; 20020091335; 20020099295; 20020099306; 20020103512; 20020107454; 20020112732; 20020117176; 20020128544; 20020138013; 20020151771; 20020177882; 20020182574; 20020183644; 20020193670; 20030001098; 20030009078; 20030023183; 20030028121; 20030032888; 20030035301; 20030036689; 20030046018; 20030055355; 20030070685; 20030093004; 20030093129; 20030100844; 20030120172; 20030130709; 20030135128; 20030139681; 20030144601; 20030149678; 20030158466; 20030158496; 20030158587; 20030160622; 20030167019; 20030171658; 20030171685; 20030176804; 20030181821; 20030185408; 20030195429; 20030216654; 20030225340; 20030229291; 20030236458; 20040002635; 20040006265; 20040006376; 20040010203; 20040039268; 20040059203; 20040059241; 20040064020; 20040064066; 20040068164; 20040068199; 20040073098; 20040073129; 20040077967; 20040079372; 20040082862; 20040082876; 20040097802; 20040116784; 20040116791; 20040116798; 20040116825; 20040117098; 20040143170; 20040144925; 20040152995; 20040158300; 20040167418; 20040181162; 20040193068; 20040199482; 20040204636; 20040204637; 20040204659; 20040210146; 20040220494; 20040220782; 20040225179; 20040230105; 20040243017; 20040254493; 20040260169; 20050007091; 20050010116; 20050018858; 20050025704; 20050033154; 20050033174; 20050038354; 20050043774; 20050075568; 20050080349; 20050080828; 20050085744; 20050096517; 20050113713; 20050119586; 20050124848; 20050124863; 20050135102; 20050137494; 20050148893; 20050148894; 20050148895; 20050149123; 20050182456; 20050197590; 20050209517; 20050216071; 20050251055; 20050256385; 20050256418; 20050267362; 20050273017; 20050277813; 20050277912; 20060004298; 20060009704; 20060015034; 20060041201; 20060047187; 20060047216; 20060047324; 20060058590; 20060074334; 20060082727; 20060084877; 20060089541; 20060089549; 20060094968; 20060100530; 20060102171; 20060111644; 20060116556; 20060135880; 20060149144; 20060153396; 20060155206; 20060155207; 20060161071; 20060161075; 20060161218; 20060167370; 20060167722; 20060173364; 20060184059; 20060189880; 20060189882; 20060200016; 20060200034; 20060200035; 20060204532; 20060206033; 20060217609; 20060233390; 20060235315; 20060235324; 20060241562; 20060241718; 20060251303; 20060258896; 20060258950; 20060265022; 20060276695; 20070007454; 20070016095; 20070016264; 20070021673; 20070021675; 20070032733; 20070032737; 20070038382; 20070060830; 20070060831; 20070066914; 20070083128; 20070093721; 20070100246; 20070100251; 20070100666; 20070129647; 20070135724; 20070135728; 20070142862; 20070142873; 20070149860; 20070161919; 20070162086; 20070167694; 20070167853; 20070167858; 20070167991; 20070173733; 20070179396; 20070191688; 20070191691; 20070191697; 20070197930; 20070203448; 20070208212; 20070208269; 20070213786; 20070225581; 20070225674; 20070225932; 20070249918; 20070249952; 20070255135; 20070260151; 20070265508; 20070265533; 20070273504; 20070276270; 20070276278; 20070276279; 20070276609; 20070291832; 20080001600; 20080001735; 20080004514; 20080004904; 20080009685; 20080009772; 20080013747; 20080021332; 20080021336; 20080021340; 20080021342; 20080033266; 20080036752; 20080045823; 20080045844; 20080051669; 20080051858; 20080058668; 20080074307; 20080077010; 20080077015; 20080082018; 20080097197; 20080119716; 20080119747; 20080119900; 20080125669; 20080139953; 20080140403; 20080154111; 20080167535; 20080167540; 20080167569; 20080177195; 20080177196; 20080177197; 20080188765; 20080195166; 20080200831; 20080208072; 20080208073; 20080214902; 20080221400; 20080221472; 20080221969; 20080228100; 20080242521; 20080243014; 20080243017; 20080243021; 20080249430; 20080255469; 20080257349; 20080260212; 20080262367; 20080262371; 20080275327; 20080294019; 20080294063; 20080319326; 20080319505; 20090005675; 20090009284; 20090018429; 20090024007; 20090030476; 20090043221; 20090048530; 20090054788; 20090062660; 20090062670; 20090062676; 20090062679; 20090062680; 20090062696; 20090076339; 20090076399; 20090076400; 20090076407; 20090082689; 20090082690; 20090083071; 20090088658; 20090094305; 20090112281; 20090118636; 20090124869; 20090124921; 20090124922; 20090124923; 20090137915; 20090137923; 20090149148; 20090156954; 20090156956; 20090157662; 20090171232; 20090171240; 20090177090; 20090177108; 20090179642; 20090182211; 20090192394; 20090198144; 20090198145; 20090204015; 20090209835; 20090216091; 20090216146; 20090227876; 20090227877; 20090227882; 20090227889; 20090240119; 20090247893; 20090247894; 20090264785; 20090264952; 20090275853; 20090287107; 20090292180; 20090297000; 20090306534; 20090312663; 20090312664; 20090312808; 20090312817; 20090316925; 20090318779; 20090323049; 20090326353; 20100010364; 20100023089; 20100030073; 20100036211; 20100036276; 20100041962; 20100042011; 20100043795; 20100049069; 20100049075; 20100049482; 20100056939; 20100069762; 20100069775; 20100076333; 20100076338; 20100079292; 20100087900; 20100094103; 20100094152; 20100094155; 20100099954; 20100106044; 20100114813; 20100130869; 20100137728; 20100137937; 20100143256; 20100152621; 20100160737; 20100174161; 20100179447; 20100185113; 20100191124; 20100191139; 20100191305; 20100195770; 20100198098; 20100198101; 20100204614; 20100204748; 20100204750; 20100217100; 20100217146; 20100217348; 20100222694; 20100224188; 20100234705; 20100234752; 20100234753; 20100245093; 20100249627; 20100249635; 20100258126; 20100261977; 20100262377; 20100268055; 20100280403; 20100286549; 20100286747; 20100292752; 20100293115; 20100298735; 20100303101; 20100312188; 20100318025; 20100324441; 20100331649; 20100331715; 20110004115; 20110009715; 20110009729; 20110009752; 20110015501; 20110015536; 20110028802; 20110028859; 20110034822; 20110038515; 20110040202; 20110046473; 20110054279; 20110054345; 20110066005; 20110066041; 20110066042; 20110066053; 20110077538; 20110082381; 20110087125; 20110092834; 20110092839; 20110098583; 20110105859; 20110105915; 20110105938; 20110106206; 20110112379; 20110112381; 20110112426; 20110112427; 20110115624; 20110118536; 20110118618; 20110118619; 20110119212; 20110125046; 20110125048; 20110125238; 20110130675; 20110144520; 20110152710; 20110160607; 20110160608; 20110160795; 20110162645; 20110178441; 20110178581; 20110181422; 20110184650; 20110190600; 20110196693; 20110208539; 20110218453; 20110218950; 20110224569; 20110224570; 20110224602; 20110245709; 20110251583; 20110251985; 20110257517; 20110263995; 20110270117; 20110270579; 20110282234; 20110288424; 20110288431; 20110295142; 20110295143; 20110295338; 20110301436; 20110301439; 20110301441; 20110301448; 20110301486; 20110301487; 20110307029; 20110307079; 20110313308; 20110313760; 20110319724; 20120004561; 20120004564; 20120004749; 20120010536; 20120016218; 20120016252; 20120022336; 20120022350; 20120022351; 20120022365; 20120022384; 20120022392; 20120022844; 20120029320; 20120029378; 20120029379; 20120035431; 20120035433; 20120035765; 20120041330; 20120046711; 20120053433; 20120053491; 20120059273; 20120065536; 20120078115; 20120083700; 20120083701; 20120088987; 20120088992; 20120089004; 20120092156; 20120092157; 20120095352; 20120095357; 20120100514; 20120101387; 20120101401; 20120101402; 20120101430; 20120108999; 20120116235; 20120123232; 20120123290; 20120125337; 20120136242; 20120136605; 20120143074; 20120143075; 20120149997; 20120150545; 20120157963; 20120159656; 20120165624; 20120165631; 20120172682; 20120172689; 20120172743; 20120191000; 20120197092; 20120197153; 20120203087; 20120203130; 20120203131; 20120203133; 20120203725; 20120209126; 20120209136; 20120209139; 20120220843; 20120220889; 20120221310; 20120226334; 20120238890; 20120242501; 20120245464; 20120245481; 20120253141; 20120253219; 20120253249; 20120265080; 20120271190; 20120277545; 20120277548; 20120277816; 20120296182; 20120296569; 20120302842; 20120302845; 20120302856; 20120302894; 20120310100; 20120310105; 20120321759; 20120323132; 20120330109; 20130006124; 20130009783; 20130011819; 20130012786; 20130012787; 20130012788; 20130012789; 20130012790; 20130012802; 20130012830; 20130013327; 20130023783; 20130030257; 20130035579; 20130039498; 20130041235; 20130046151; 20130046193; 20130046715; 20130060110; 20130060125; 20130066392; 20130066394; 20130066395; 20130069780; 20130070929; 20130072807; 20130076885; 20130079606; 20130079621; 20130079647; 20130079656; 20130079657; 20130080127; 20130080489; 20130095459; 20130096391; 20130096393; 20130096394; 20130096408; 20130096441; 20130096839; 20130096840; 20130102833; 20130102897; 20130109995; 20130109996; 20130116520; 20130116561; 20130116588; 20130118494; 20130123584; 20130127708; 20130130799; 20130137936; 20130137938; 20130138002; 20130144106; 20130144107; 20130144108; 20130144183; 20130150650; 20130150651; 20130150659; 20130159041; 20130165812; 20130172686; 20130172691; 20130172716; 20130172763; 20130172767; 20130172772; 20130172774; 20130178718; 20130182860; 20130184552; 20130184558; 20130184603; 20130188854; 20130190577; 20130190642; 20130197321; 20130197322; 20130197328; 20130197339; 20130204150; 20130211224; 20130211276; 20130211291; 20130217982; 20130218043; 20130218053; 20130218233; 20130221961; 20130225940; 20130225992; 20130231574; 20130231580; 20130231947; 20130238049; 20130238050; 20130238063; 20130245422; 20130245486; 20130245711; 20130245712; 20130266163; 20130267760; 20130267866; 20130267928; 20130274580; 20130274625; 20130275159; 20130281811; 20130282339; 20130289401; 20130289413; 20130289417; 20130289424; 20130289433; 20130295016; 20130300573; 20130303828; 20130303934; 20130304153; 20130310660; 20130310909; 20130324880; 20130338449; 20130338459; 20130344465; 20130345522; 20130345523; 20140005988; 20140012061; 20140012110; 20140012133; 20140012153; 20140018792; 20140019165; 20140023999; 20140025396; 20140025397; 20140038147; 20140046208; 20140051044; 20140051960; 20140051961; 20140052213; 20140055284; 20140058241; 20140066739; 20140066763; 20140070958; 20140072127; 20140072130; 20140073863; 20140073864; 20140073866; 20140073870; 20140073875; 20140073876; 20140073877; 20140073878; 20140073898; 20140073948; 20140073949; 20140073951; 20140073953; 20140073954; 20140073955; 20140073956; 20140073960; 20140073961; 20140073963; 20140073965; 20140073966; 20140073967; 20140073968; 20140073974; 20140073975; 20140074060; 20140074179; 20140074180; 20140077946; 20140081114; 20140081115; 20140094720; 20140098981; 20140100467; 20140104059; 20140105436; 20140107464; 20140107519; 20140107525; 20140114165; 20140114205; 20140121446; 20140121476; 20140121554; 20140128762; 20140128764; 20140135879; 20140136585; 20140140567; 20140143064; 20140148723; 20140152673; 20140155706; 20140155714; 20140155730; 20140156000; 20140163328; 20140163330; 20140163331; 20140163332; 20140163333; 20140163335; 20140163336; 20140163337; 20140163385; 20140163409; 20140163425; 20140163897; 20140171820; 20140175261; 20140176944; 20140179980; 20140180088; 20140180092; 20140180093; 20140180094; 20140180095; 20140180096; 20140180097; 20140180099; 20140180100; 20140180112; 20140180113; 20140180145; 20140180153; 20140180160; 20140180161; 20140180176; 20140180177; 20140180597; 20140187994; 20140188006; 20140188770; 20140194702; 20140194758; 20140194759; 20140194768; 20140194769; 20140194780; 20140194793; 20140203797; 20140213937; 20140214330; 20140228651; 20140228702; 20140232516; 20140235965; 20140236039; 20140236077; 20140237073; 20140243614; 20140243621; 20140243628; 20140243694; 20140249429; 20140257073; 20140257147; 20140266696; 20140266787; 20140275886; 20140275889; 20140275891; 20140276013; 20140276014; 20140276090; 20140276123; 20140276130; 20140276181; 20140276183; 20140279746; 20140288381; 20140288614; 20140288953; 20140289172; 20140296724; 20140303453; 20140303454; 20140303508; 20140309943; 20140313303; 20140316217; 20140316221; 20140316230; 20140316235; 20140316278; 20140323900; 20140324118; 20140330102; 20140330157; 20140330159; 20140330334; 20140330404; 20140336473; 20140347491; 20140350431; 20140350436; 20140358025; 20140364721; 20140364746; 20140369537; 20140371544; 20140371599; 20140378809; 20140378810; 20140379620; 20150003698; 20150003699; 20150005592; 20150005594; 20150005640; 20150005644; 20150005660; 20150005680; 20150006186; 20150016618; 20150018758; 20150025351; 20150025422; 20150032017; 20150038804; 20150038869; 20150039110; 20150042477; 20150045686; 20150051663; 20150057512; 20150065839; 20150073237; 20150073306; 20150080671; 20150080746; 20150087931; 20150088024; 20150092949; 20150093729; 20150099941; 20150099962; 20150103360; 20150105631; 20150105641; 20150105837; 20150112222; 20150112409; 20150119652; 20150119743; 20150119746; 20150126821; 20150126845; 20150126848; 20150126873; 20150134264; 20150137988; 20150141529; 20150141789; 20150141794; 20150153477; 20150157235; 20150157266; 20150164349; 20150164362; 20150164375; 20150164404; 20150181840; 20150182417; 20150190070; 20150190085; 20150190636; 20150190637; 20150196213; 20150199010; 20150201879; 20150202447; 20150203822; 20150208940; 20150208975; 20150213191; 20150216436; 20150216468; 20150217082; 20150220486; 20150223743; 20150227702; 20150230750; 20150231408; 20150238106; 20150238112; 20150238137; 20150245800; 20150247921; 20150250393; 20150250401; 20150250415; 20150257645; 20150257673; 20150257674; 20150257700; 20150257712; 20150265164; 20150269825; 20150272465; 20150282730; 20150282755; 20150282760; 20150290420; 20150290453; 20150290454; 20150297106; 20150297141; 20150304101; 20150305685; 20150309563; 20150313496; 20150313535; 20150327813; 20150327837; 20150335292; 20150342478; 20150342493; 20150351655; 20150351701; 20150359441; 20150359450; 20150359452; 20150359467; 20150359486; 20150359492; 20150366497; 20150366504; 20150366516; 20150366518; 20150374285; 20150374292; 20150374300; 20150380009; 20160000348; 20160000354; 20160007915; 20160007918; 20160012749; 20160015281; 20160015289; 20160022141; 20160022156; 20160022164; 20160022167; 20160022206; 20160027293; 20160029917; 20160029918; 20160029946; 20160029950; 20160029965; 20160030702; 20160038037; 20160038038; 20160038049; 20160038091; 20160045150; 20160045756; 20160051161; 20160051162; 20160051187; 20160051195; 20160055415; 20160058301; 20160066788; 20160067494; 20160073886; 20160074661; 20160081577; 20160081616; 20160087603; 20160089031; 20160100769; 20160101260; 20160106331; 20160106344; 20160112022; 20160112684; 20160113539; 20160113545; 20160113567; 20160113587; 20160119726; 20160120433; 20160120434; 20160120464; 20160120480; 20160128596; 20160132654; 20160135691; 20160135727; 20160135754; 20160140834; 20160143554; 20160143560; 20160143594; 20160148531; 20160150988; 20160151014; 20160151018; 20160151628; 20160157742; 20160157828; 20160162652; 20160165852; 20160165853; 20160166169; 20160166197; 20160166199; 20160166208; 20160174099; 20160174863; 20160178392; 20160183828; 20160183861; 20160191517; 20160192841; 20160192842; 20160192847; 20160192879; 20160196758; 20160198963; 20160198966; 20160202755; 20160206877; 20160206880; 20160213276; 20160213314; 20160220133; 20160220134; 20160220136; 20160220166; 20160220836; 20160220837; 20160224757; 20160228019; 20160228029; 20160228059; 20160228705; 20160232811; 20160235324; 20160235351; 20160235352; 20160239084; 20160242659; 20160242690; 20160242699; 20160248434; 20160249841; 20160256063; 20160256112; 20160256118; 20160259905; 20160262664; 20160262685; 20160262695; 20160262703; 20160278651; 20160278697; 20160278713; 20160282941; 20160287120; 20160287157; 20160287162; 20160287166; 20160287871; 20160296157; 20160302683; 20160302704; 20160302709; 20160302720; 20160302737; 20160303402; 20160310031; 20160310070; 20160317056; 20160324465; 20160331264; 20160338634; 20160338644; 20160338798; 20160346542; 20160354003; 20160354027; 20160360965; 20160360970; 20160361021; 20160361041; 20160367204; 20160374581; 20160374618; 20170000404; 20170001016; 20170007165; 20170007173; 20170014037; 20170014083; 20170020434; 20170020447; 20170027467; 20170032098; 20170035392; 20170042430; 20170042469; 20170042475; 20170053513; 20170055839; 20170055898; 20170055913; 20170065199; 20170065218; 20170065229; 20170071495; 20170071523; 20170071529; 20170071532; 20170071537; 20170071546; 20170071551; 20170071552; 20170079538; 20170079596; 20170086672; 20170086695; 20170091567; 20170095721; 20170105647; 20170112379; 20170112427; 20170120066; 20170127946; 20170132816; 20170135597; 20170135604; 20170135626; 20170135629; 20170135631; 20170135633; 20170143231; 20170143249; 20170143255; 20170143257; 20170143259; 20170143266; 20170143267; 20170143268; 20170143273; 20170143280; 20170143282; 20170143960; 20170143963; 20170146386; 20170146387; 20170146390; 20170146391; 20170147754; 20170148240; 20170150896; 20170150916; 20170156593; 20170156606; 20170156655; 20170164878; 20170164901; 20170172414; 20170172501; 20170172520; 20170173262; 20170177023; 20170181693; 20170185149; 20170188865; 20170188872; 20170188947; 20170188992; 20170189691; 20170196497; 20170202474; 20170202518; 20170203154; 20170209053; and 20170209083.

There are many approaches to time-frequency decomposition of EEG data, including the short-term Fourier transform (STFT), (Gabor D. Theory of Communication. J. Inst. Electr. Engrs. 1946; 93:429-457) continuous (Daubechies I. Ten Lectures on Wavelets. Philadelphia, Pa. Society for Industrial and Applied Mathematics; 1992:357.21. Combes J M, Grossmann A, Tchamitchian P. Wavelets: Time-Frequency Methods and Phase Space-Proceedings of the International Conference; Dec. 14-18, 1987; Marseille, France) or discrete (Mallat S G. A theory for multiresolution signal decomposition: the wavelet representation. IEEE Trans Pattern Anal Mach Intell. 1989; 11:674-693) wavelet transforms, Hilbert transform (Lyons R G. Understanding Digital Signal Processing. 2nd ed. Upper Saddle River, N.J.: Prentice Hall PTR; 2004:688), and matching pursuits (Mallat S, Zhang Z. Matching pursuits with time-frequency dictionaries. IEEE Trans. Signal Proc. 1993; 41(12):3397-3415). Prototype analysis systems may be implemented using, for example, MatLab with the Wavelet Toolbox, www.mathworks.com/products/wavelet.html.

See, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 6,196,972; 6,338,713; 6,442,421; 6,507,754; 6,524,249; 6,547,736; 6,616,611; 6,816,744; 6,865,494; 6,915,241; 6,936,012; 6,996,261; 7,043,293; 7,054,454; 7,079,977; 7,128,713; 7,146,211; 7,149,572; 7,164,941; 7,209,788; 7,254,439; 7,280,867; 7,282,030; 7,321,837; 7,330,032; 7,333,619; 7,381,185; 7,537,568; 7,559,903; 7,565,193; 7,567,693; 7,604,603; 7,624,293; 7,640,055; 7,715,919; 7,725,174; 7,729,755; 7,751,878; 7,778,693; 7,794,406; 7,797,040; 7,801,592; 7,803,118; 7,803,119; 7,879,043; 7,896,807; 7,899,524; 7,917,206; 7,933,646; 7,937,138; 7,976,465; 8,014,847; 8,033,996; 8,073,534; 8,095,210; 8,137,269; 8,137,270; 8,175,696; 8,177,724; 8,177,726; 8,180,601; 8,187,181; 8,197,437; 8,233,965; 8,236,005; 8,244,341; 8,248,069; 8,249,698; 8,280,514; 8,295,914; 8,326,433; 8,335,664; 8,346,342; 8,355,768; 8,386,312; 8,386,313; 8,392,250; 8,392,253; 8,392,254; 8,392,255; 8,396,542; 8,406,841; 8,406,862; 8,412,655; 8,428,703; 8,428,704; 8,463,374; 8,464,288; 8,475,387; 8,483,815; 8,494,610; 8,494,829; 8,494,905; 8,498,699; 8,509,881; 8,533,042; 8,548,786; 8,571,629; 8,579,786; 8,591,419; 8,606,360; 8,628,480; 8,655,428; 8,666,478; 8,682,422; 8,706,183; 8,706,205; 8,718,747; 8,725,238; 8,738,136; 8,747,382; 8,755,877; 8,761,869; 8,762,202; 8,768,449; 8,781,796; 8,790,255; 8,790,272; 8,821,408; 8,825,149; 8,831,731; 8,843,210; 8,849,392; 8,849,632; 8,855,773; 8,858,440; 8,862,210; 8,862,581; 8,903,479; 8,918,178; 8,934,965; 8,951,190; 8,954,139; 8,955,010; 8,958,868; 8,983,628; 8,983,629; 8,989,835; 9,020,789; 9,026,217; 9,031,644; 9,050,470; 9,060,671; 9,070,492; 9,072,832; 9,072,905; 9,078,584; 9,084,896; 9,095,295; 9,101,276; 9,107,595; 9,116,835; 9,125,574; 9,149,719; 9,155,487; 9,192,309; 9,198,621; 9,204,835; 9,211,417; 9,215,978; 9,232,910; 9,232,984; 9,238,142; 9,242,067; 9,247,911; 9,248,286; 9,254,383; 9,277,871; 9,277,873; 9,282,934; 9,289,603; 9,302,110; 9,307,944; 9,308,372; 9,320,450; 9,336,535; 9,357,941; 9,375,151; 9,375,171; 9,375,571; 9,403,038; 9,415,219; 9,427,581; 9,443,141; 9,451,886; 9,454,646; 9,462,956; 9,462,975; 9,468,541; 9,471,978; 9,480,402; 9,492,084; 9,504,410; 9,522,278; 9,533,113; 9,545,285; 9,560,984; 9,563,740; 9,615,749; 9,616,166; 9,622,672; 9,622,676; 9,622,702; 9,622,703; 9,623,240; 9,636,019; 9,649,036; 9,659,229; 9,668,694; 9,681,814; 9,681,820; 9,682,232; 9,713,428; 20020035338; 20020091319; 20020095099; 20020103428; 20020103429; 20020193670; 20030032889; 20030046018; 20030093129; 20030160622; 20030185408; 20030216654; 20040039268; 20040049484; 20040092809; 20040133119; 20040133120; 20040133390; 20040138536; 20040138580; 20040138711; 20040152958; 20040158119; 20050010091; 20050018858; 20050033174; 20050075568; 20050085744; 20050119547; 20050148893; 20050148894; 20050148895; 20050154290; 20050167588; 20050240087; 20050245796; 20050267343; 20050267344; 20050283053; 20050283090; 20060020184; 20060036152; 20060036153; 20060074290; 20060078183; 20060135879; 20060153396; 20060155495; 20060161384; 20060173364; 20060200013; 20060217816; 20060233390; 20060281980; 20070016095; 20070066915; 20070100278; 20070179395; 20070179734; 20070191704; 20070209669; 20070225932; 20070255122; 20070255135; 20070260151; 20070265508; 20070287896; 20080021345; 20080033508; 20080064934; 20080074307; 20080077015; 20080091118; 20080097197; 20080119716; 20080177196; 20080221401; 20080221441; 20080243014; 20080243017; 20080255949; 20080262367; 20090005667; 20090033333; 20090036791; 20090054801; 20090062676; 20090177144; 20090220425; 20090221930; 20090270758; 20090281448; 20090287271; 20090287272; 20090287273; 20090287467; 20090299169; 20090306534; 20090312646; 20090318794; 20090322331; 20100030073; 20100036211; 20100049276; 20100068751; 20100069739; 20100094152; 20100099975; 20100106041; 20100198090; 20100204604; 20100204748; 20100249638; 20100280372; 20100331976; 20110004115; 20110015515; 20110015539; 20110040713; 20110066041; 20110066042; 20110074396; 20110077538; 20110092834; 20110092839; 20110098583; 20110160543; 20110172725; 20110178441; 20110184305; 20110191350; 20110218950; 20110257519; 20110270074; 20110282230; 20110288431; 20110295143; 20110301441; 20110313268; 20110313487; 20120004518; 20120004561; 20120021394; 20120022343; 20120029378; 20120041279; 20120046535; 20120053473; 20120053476; 20120053478; 20120053479; 20120083708; 20120108918; 20120108997; 20120143038; 20120145152; 20120150545; 20120157804; 20120159656; 20120172682; 20120184826; 20120197153; 20120209139; 20120253261; 20120265267; 20120271151; 20120271376; 20120289869; 20120310105; 20120321759; 20130012804; 20130041235; 20130060125; 20130066392; 20130066395; 20130072775; 20130079621; 20130102897; 20130116520; 20130123607; 20130127708; 20130131438; 20130131461; 20130165804; 20130167360; 20130172716; 20130172772; 20130178733; 20130184597; 20130204122; 20130211238; 20130223709; 20130226261; 20130237874; 20130238049; 20130238050; 20130245416; 20130245424; 20130245485; 20130245486; 20130245711; 20130245712; 20130261490; 20130274562; 20130289364; 20130295016; 20130310422; 20130310909; 20130317380; 20130338518; 20130338803; 20140039279; 20140057232; 20140058218; 20140058528; 20140074179; 20140074180; 20140094710; 20140094720; 20140107521; 20140142654; 20140148657; 20140148716; 20140148726; 20140180153; 20140180160; 20140187901; 20140228702; 20140243647; 20140243714; 20140257128; 20140275807; 20140276130; 20140276187; 20140303454; 20140303508; 20140309614; 20140316217; 20140316248; 20140324118; 20140330334; 20140330335; 20140330336; 20140330404; 20140335489; 20140350634; 20140350864; 20150005646; 20150005660; 20150011907; 20150018665; 20150018699; 20150018702; 20150025422; 20150038869; 20150073294; 20150073306; 20150073505; 20150080671; 20150080695; 20150099962; 20150126821; 20150151142; 20150164431; 20150190070; 20150190636; 20150190637; 20150196213; 20150196249; 20150213191; 20150216439; 20150245800; 20150248470; 20150248615; 20150272652; 20150297106; 20150297893; 20150305686; 20150313498; 20150366482; 20150379370; 20160000348; 20160007899; 20160022167; 20160022168; 20160022207; 20160027423; 20160029965; 20160038042; 20160038043; 20160045128; 20160051812; 20160058304; 20160066838; 20160107309; 20160113587; 20160120428; 20160120432; 20160120437; 20160120457; 20160128596; 20160128597; 20160135754; 20160143594; 20160144175; 20160151628; 20160157742; 20160157828; 20160174863; 20160174907; 20160176053; 20160183881; 20160184029; 20160198973; 20160206380; 20160213261; 20160213317; 20160220850; 20160228028; 20160228702; 20160235324; 20160239966; 20160239968; 20160242645; 20160242665; 20160242669; 20160242690; 20160249841; 20160250355; 20160256063; 20160256105; 20160262664; 20160278653; 20160278713; 20160287117; 20160287162; 20160287169; 20160287869; 20160303402; 20160331264; 20160331307; 20160345895; 20160345911; 20160346542; 20160361041; 20160361546; 20160367186; 20160367198; 20170031440; 20170031441; 20170039706; 20170042444; 20170045601; 20170071521; 20170079588; 20170079589; 20170091418; 20170113046; 20170120041; 20170128015; 20170135594; 20170135626; 20170136240; 20170165020; 20170172446; 20170173326; 20170188870; 20170188905; 20170188916; 20170188922; and 20170196519.

Single instruction, multiple data processors, such as graphic processing units including the nVidia CUDA environment or AMD Firepro high-performance computing environment are known, and may be employed for general purpose computing, finding particular application in data matrix transformations.

See, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 5,273,038; 5,503,149; 6,240,308; 6,272,370; 6,298,259; 6,370,414; 6,385,479; 6,490,472; 6,556,695; 6,697,660; 6,801,648; 6,907,280; 6,996,261; 7,092,748; 7,254,500; 7,338,455; 7,346,382; 7,490,085; 7,497,828; 7,539,528; 7,565,193; 7,567,693; 7,577,472; 7,597,665; 7,627,370; 7,680,526; 7,729,755; 7,809,434; 7,840,257; 7,860,548; 7,872,235; 7,899,524; 7,904,134; 7,904,139; 7,907,998; 7,983,740; 7,983,741; 8,000,773; 8,014,847; 8,069,125; 8,233,682; 8,233,965; 8,235,907; 8,248,069; 8,356,004; 8,379,952; 8,406,838; 8,423,125; 8,445,851; 8,553,956; 8,586,932; 8,606,349; 8,615,479; 8,644,910; 8,679,009; 8,696,722; 8,712,512; 8,718,747; 8,761,866; 8,781,557; 8,814,923; 8,821,376; 8,834,546; 8,852,103; 8,870,737; 8,936,630; 8,951,189; 8,951,192; 8,958,882; 8,983,155; 9,005,126; 9,020,586; 9,022,936; 9,028,412; 9,033,884; 9,042,958; 9,078,584; 9,101,279; 9,135,400; 9,144,392; 9,149,255; 9,155,521; 9,167,970; 9,179,854; 9,179,858; 9,198,637; 9,204,835; 9,208,558; 9,211,077; 9,213,076; 9,235,685; 9,242,067; 9,247,924; 9,268,014; 9,268,015; 9,271,651; 9,271,674; 9,275,191; 9,292,920; 9,307,925; 9,322,895; 9,326,742; 9,330,206; 9,368,265; 9,395,425; 9,402,558; 9,414,776; 9,436,989; 9,451,883; 9,451,899; 9,468,541; 9,471,978; 9,480,402; 9,480,425; 9,486,168; 9,592,389; 9,615,789; 9,626,756; 9,672,302; 9,672,617; 9,682,232; 20020033454; 20020035317; 20020037095; 20020042563; 20020058867; 20020103428; 20020103429; 20030018277; 20030093004; 20030128801; 20040082862; 20040092809; 20040096395; 20040116791; 20040116798; 20040122787; 20040122790; 20040166536; 20040215082; 20050007091; 20050020918; 20050033154; 20050079636; 20050119547; 20050154290; 20050222639; 20050240253; 20050283053; 20060036152; 20060036153; 20060052706; 20060058683; 20060074290; 20060078183; 20060084858; 20060149160; 20060161218; 20060241382; 20060241718; 20070191704; 20070239059; 20080001600; 20080009772; 20080033291; 20080039737; 20080042067; 20080097235; 20080097785; 20080128626; 20080154126; 20080221441; 20080228077; 20080228239; 20080230702; 20080230705; 20080249430; 20080262327; 20080275340; 20090012387; 20090018407; 20090022825; 20090024050; 20090062660; 20090078875; 20090118610; 20090156907; 20090156955; 20090157323; 20090157481; 20090157482; 20090157625; 20090157751; 20090157813; 20090163777; 20090164131; 20090164132; 20090171164; 20090172540; 20090179642; 20090209831; 20090221930; 20090246138; 20090299169; 20090304582; 20090306532; 20090306534; 20090312808; 20090312817; 20090318773; 20090318794; 20090322331; 20090326604; 20100021378; 20100036233; 20100041949; 20100042011; 20100049482; 20100069739; 20100069777; 20100082506; 20100113959; 20100249573; 20110015515; 20110015539; 20110028827; 20110077503; 20110118536; 20110125077; 20110125078; 20110129129; 20110160543; 20110161011; 20110172509; 20110172553; 20110178359; 20110190846; 20110218405; 20110224571; 20110230738; 20110257519; 20110263962; 20110263968; 20110270074; 20110288400; 20110301448; 20110306845; 20110306846; 20110313274; 20120021394; 20120022343; 20120035433; 20120053483; 20120163689; 20120165904; 20120215114; 20120219195; 20120219507; 20120245474; 20120253261; 20120253434; 20120289854; 20120310107; 20120316793; 20130012804; 20130060125; 20130063550; 20130085678; 20130096408; 20130110616; 20130116561; 20130123607; 20130131438; 20130131461; 20130178693; 20130178733; 20130184558; 20130211238; 20130221961; 20130245424; 20130274586; 20130289385; 20130289386; 20130303934; 20140058528; 20140066763; 20140119621; 20140151563; 20140155730; 20140163368; 20140171757; 20140180088; 20140180092; 20140180093; 20140180094; 20140180095; 20140180096; 20140180097; 20140180099; 20140180100; 20140180112; 20140180113; 20140180176; 20140180177; 20140184550; 20140193336; 20140200414; 20140243614; 20140257047; 20140275807; 20140303486; 20140315169; 20140316248; 20140323849; 20140335489; 20140343397; 20140343399; 20140343408; 20140364721; 20140378830; 20150011866; 20150038812; 20150051663; 20150099959; 20150112409; 20150119658; 20150119689; 20150148700; 20150150473; 20150196800; 20150200046; 20150219732; 20150223905; 20150227702; 20150247921; 20150248615; 20150253410; 20150289779; 20150290453; 20150290454; 20150313540; 20150317796; 20150324692; 20150366482; 20150375006; 20160005320; 20160027342; 20160029965; 20160051161; 20160051162; 20160055304; 20160058304; 20160058392; 20160066838; 20160103487; 20160120437; 20160120457; 20160143541; 20160157742; 20160184029; 20160196393; 20160228702; 20160231401; 20160239966; 20160239968; 20160260216; 20160267809; 20160270723; 20160302720; 20160303397; 20160317077; 20160345911; 20170027539; 20170039706; 20170045601; 20170061034; 20170085855; 20170091418; 20170112403; 20170113046; 20170120041; 20170160360; 20170164861; 20170169714; 20170172527; and 20170202475.

Statistical analysis may be presented in a form that permits parallelization, which can be efficiently implemented using various parallel processors, a common form of which is a SIMD (single instruction, multiple data) processor, found in typical graphics processors (GPUs).

See, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 8,406,890; 8,509,879; 8,542,916; 8,852,103; 8,934,986; 9,022,936; 9,028,412; 9,031,653; 9,033,884; 9,037,530; 9,055,974; 9,149,255; 9,155,521; 9,198,637; 9,247,924; 9,268,014; 9,268,015; 9,367,131; 9,4147,80; 9,420,970; 9,430,615; 9,442,525; 9,444,998; 9,445,763; 9,462,956; 9,474,481; 9,489,854; 9,504,420; 9,510,790; 9,519,981; 9,526,906; 9,538,948; 9,585,581; 9,622,672; 9,641,665; 9,652,626; 9,684,335; 9,687,187; 9,693,684; 9,693,724; 9,706,963; 9,712,736; 20090118622; 20100098289; 20110066041; 20110066042; 20110098583; 20110301441; 20120130204; 20120265271; 20120321759; 20130060158; 20130113816; 20130131438; 20130184786; 20140031889; 20140031903; 20140039975; 20140114889; 20140226131; 20140279341; 20140296733; 20140303424; 20140313303; 20140315169; 20140316235; 20140364721; 20140378810; 20150003698; 20150003699; 20150005640; 20150005644; 20150006186; 20150029087; 20150033245; 20150033258; 20150033259; 20150033262; 20150033266; 20150081226; 20150088093; 20150093729; 20150105701; 20150112899; 20150126845; 20150150122; 20150190062; 20150190070; 20150190077; 20150190094; 20150192776; 20150196213; 20150196800; 20150199010; 20150241916; 20150242608; 20150272496; 20150272510; 20150282705; 20150282749; 20150289217; 20150297109; 20150305689; 20150335295; 20150351655; 20150366482; 20160027342; 20160029896; 20160058366; 20160058376; 20160058673; 20160060926; 20160065724; 20160065840; 20160077547; 20160081625; 20160103487; 20160104006; 20160109959; 20160113517; 20160120048; 20160120428; 20160120457; 20160125228; 20160157773; 20160157828; 20160183812; 20160191517; 20160193499; 20160196185; 20160196635; 20160206241; 20160213317; 20160228064; 20160235341; 20160235359; 20160249857; 20160249864; 20160256086; 20160262680; 20160262685; 20160270656; 20160278672; 20160282113; 20160287142; 20160306942; 20160310071; 20160317056; 20160324445; 20160324457; 20160342241; 20160360100; 20160361027; 20160366462; 20160367138; 20160367195; 20160374616; 20160378608; 20160378965; 20170000324; 20170000325; 20170000326; 20170000329; 20170000330; 20170000331; 20170000332; 20170000333; 20170000334; 20170000335; 20170000337; 20170000340; 20170000341; 20170000342; 20170000343; 20170000345; 20170000454; 20170000683; 20170001032; 20170007111; 20170007115; 20170007116; 20170007122; 20170007123; 20170007182; 20170007450; 20170007799; 20170007843; 20170010469; 20170010470; 20170013562; 20170017083; 20170020627; 20170027521; 20170028563; 20170031440; 20170032221; 20170035309; 20170035317; 20170041699; 20170042485; 20170046052; 20170065349; 20170086695; 20170086727; 20170090475; 20170103440; 20170112446; 20170113056; 20170128006; 20170143249; 20170143442; 20170156593; 20170156606; 20170164893; 20170171441; 20170172499; 20170173262; 20170185714; 20170188933; 20170196503; 20170205259; 20170206913; and 20170214786.

Artificial neural networks have been employed to analyze EEG signals.

See, U.S. Patent and Pub. App. Nos. U.S. Pat. No. 9,443,141; 20110218950; 20150248167; 20150248764; 20150248765; 20150310862; 20150331929; 20150338915; 20160026913; 20160062459; 20160085302; 20160125572; 20160247064; 20160274660; 20170053665; 20170069306; 20170173262; and 20170206691.

Amari, S., Natural gradient works efficiently in learning, Neural Computation 10:251-276, 1998.

Amari S., Cichocki, A. & Yang, H. H., A new learning algorithm for blind signal separation. In: Advances in Neural Information Processing Systems 8, MIT Press, 1996.

Bandettini P A, Wong E C, Hinks R S, Tikofsky R S, Hyde J S, Time course EPI of human brain function during task activation. Magn Reson Med 25:390-7, 1992.

Bell A. J. & Sejnowski T. J. An information-maximization approach to blind separation and blind deconvolution. Neural Comput 7:1129-59, 1995.

Bell, A. J. & Sejnowski, T. J., Learning the higher-order structure of a natural sound, Network: Computation in Neural Systems 7, 1996b.

Bench C J, Frith C D, Grasby P M, Friston K J, Paulesu E, Frackowiak R S, Dolan R J, Investigations of the functional anatomy of attention using the Stroop test Neuropsychologia 31:907-22, 1993.

Boynton G M, Engel S A, Glover G H, Heeger D J, Linear systems analysis of functional magnetic resonance imaging in human V1. J Neurosci 16:4207-21., 1996.

Bringer, Julien, Hervé Chabanne, and Bruno Kindarji. “Error-tolerant searchable encryption.” In Communications, 2009. ICC'09. IEEE International Conference on, pp. 1-6. IEEE, 2009.

Buckner, R. L., Bandettini, P. A, O'Craven, K M, Savoy, R. L., Petersen, S. E., Raichle, M. E. & Rosen, B. R., Proc Natl Acad Sci USA 93, 14878-83, 1996.

Cardoso, J-F. & Laheld, B., Equivalent adaptive source separation, IEEE Trans. Signal Proc., in press.

Chapman, R. M. & McCrary, J. W., EP component identification and measurement by principal components analysis. Brain Lang. 27, 288-301, 1995.

Cichocki A., Unbehauen R., & Rummert E., Robust learning algorithm for blind separation of signals, Electronics Letters 30, 1386-1387, 1994.

Comon P, Independent component analysis, A new concept? Signal Processing 36:11-20, 1994.

Cover, T. M. & Thomas, J. A., Elements of Information Theory John Wiley, 1991.

Cox, R. W., AFNI: software for analysis and visualization of functional magnetic resonance neuroimages. Comput Biomed Res 29:162-73, 1996.

Cox, R. W. & Hyde J. S. Software tools for analysis and visualization of fMRI data, NMR in Biomedicine, in press.

Dale, A. M. & Sereno, M. I., Improved localization of cortical activity by combining EEG and MEG with MRI cortical surface reconstruction—a linear approach. J. Cogn. Neurosci. 5:162-176, 1993.

Friston K. J., Modes or models: A critique on independent component analysis for fMRI. Trends in Cognitive Sciences, in press.

Friston K. J., Commentary and opinion: II. Statistical parametric mapping: ontology and current issues. J Cereb Blood Flow Metab 15:361-70, 1995.

Friston K. J., Statistical Parametric Mapping and Other Analyses of Functional Imaging Data In: A W. Toga, J. C. Mazziotta eds., Brain Mapping, The Methods. San Diego: Academic Press, 1996:363-396, 1995.

Friston K J, Frith C D, Liddle P F, Frackowiak R S, Functional connectivity: the principal-component analysis of large (PET) data sets. J Cereb Blood Flow Metab 13:5-14, 1993.

Friston K J, Holmes A P, Worsley K J, Poline J P, Frith C D, and Frackowiak R. S. J., Statistical Parametric Maps in Functional Imaging: A General Linear Approach, Human Brain Mapping 2:189-210, 1995.

Friston K J, Williams S, Howard R, Frackowiak R S and Turner R, Movement-related effects in fMRI time-series. Magn Reson Med 35:346-55, 1996.

Galambos, R. and S. Makeig, “Dynamic changes in steady-state potentials,” in: Dynamics of Sensory and Cognitive Processing of the Brain, ed. E. Basar Springer, pp. 178-199, 1987.

Galambos, R., S. Makeig, and P. Talmachoff, A 40 Hz auditory potential recorded from the human scalp, Proc Natl Acad Sci USA 78(4):2643-2647, 1981.

Gail, Zvi, Stuart Haber, and Moti Yung. “Cryptographic computation: Secure fault-tolerant protocols and the public-key model.” In Conference on the Theory and Application of Cryptographic Techniques, pp. 135-155. Springer, Berlin, Heidelberg, 1987.

George J S, Aine C J, Mosher J C, Schmidt D M, Ranken D M, Schlitt H A, Wood C C, Lewine J D, Sanders J A, Belliveau J W. Mapping function in the human brain with magnetoencephalography, anatomical magnetic resonance imaging, and functional magnetic resonance imaging. J Clin Neurophysiol 12:406-31, 1995.

Ives, J. R, Warach S, Schmitt F, Edelman R R and Schomer D L. Monitoring the patient's EEG during echo planar MRI, Electroencephalogr Clin Neurophysiol, 87:417-420, 1993.

Jackson, J. E., A User's Guide to Principal Components. New York: John Wiley & Sons, Inc., 1991.

Jokeit, H. and Makeig, S., Different event-related patterns of gamma-band power in brain waves of fast- and slow-reacting subjects, Proc. Nat. Acad. Sci USA 91:6339-6343, 1994.

Juels, Ari, and Madhu Sudan. “A fuzzy vault scheme.” Designs, Codes and Cryptography 38, no. 2 (2006): 237-257.

Jueptner, M., K. M. Stephan, C. D. Frith, D. J. Brooks, R. S J. Frackowiak & R. E. Passingham, Anatomy of Motor Learning. I. Frontal Cortex and Attention. J. Neurophysiology 77:1313-1324, 1977.

Jung, T-P., Humphries, C., Lee, T-W., Makeig, S., McKeown, M., Iragui, V. and Sejnowski, T. J., “Extended ICA removes artifacts from electroencephalographic recordings,” In: Advances in Neural Information Processing Systems 10: MIT Press, Cambridge, Mass. in press.

Jung, T-P., Humphries, C., Lee, T-W., McKeown, M. J, Iragui, V., Makeig, S. & Sejnowski, T. J., Removing electroencephalographic artifacts by blind source separation, submitted-a.

Jung, T-P., S. Makeig, M. Stensmo & T. Sejnowski, Estimating Alertness from the EEG Power Spectrum, IEEE Transactions on Biomedical Engineering, 44(1), 60-69, 1997.

Jung, T-P., Makeig, S., Westerfield, M., Townsend, J., Courchesne, E. and Sejnowski, T. J., Analysis and visualization of single-trial event-related potentials, submitted-b.

Jutten, C. & Herault J., Blind separation of sources, part I: an adaptive algorithm based on neuromimetic architecture. Signal Processing 24, 1-10, 1991.

Karhumen, J., Oja, E., Wang, L, Vigario, R. & Joutsenalo, J., A class of neural networks for independent component analysis, IEEE Trans. Neural Networks, in press.

Kwong K. K., Functional magnetic resonance imaging with echo planar imaging. Magn Reson Q 11:1-20, 1995.

Kwong K. K., Belliveau J W, Chester D A, Goldberg I E, Weisskoff R M, Poncelet B P, Kennedy D N, Hoppel B E, Cohen M S, Turner R, et al., Dynamic magnetic resonance imaging of human brain activity during primary sensory stimulation. Proc Natl Acad Sci USA 89:5675-9, 1992.

Lee, T.-W., Girolami, M., and Sejnowski, T. J., Independent component analysis using an extended infomax algorithm for mixed Sub-gaussian and Super-gaussian sources, Neural Computation, submitted for publication.

Lewicki, Michael S., and Sejnowski, Terence J., Learning nonlinear overcomplete representations for efficient coding, Eds. M. Keams, M. Jordan, and S. Solla, Advances in Neural Information Processing Systems 10, in press.

Linsker, R., Local synaptic learning rules suffice to maximise mutual information in a linear network Neural Computation 4, 691-702, 1992.

Liu A K, Belliveau J W, Dale A M. Spatiotemporal imaging of human brain activity using functional MRI-constrained magnetoencephalography data: Monte Carlo simulations. Proc Natl Acad Sci USA 95:8945-50, 1998

Manoach D S, Schlaug G, Siewert B, Darby D G, Bly B M, Benfield A, Edelman R R, Warach S, Prefrontal cortex fMRI signal changes are correlated with working memory load. Neuroreport 8:545-9, 1997.

McCarthy, G., Luby, M., Gore, J. and Goldman-Rakb, P., Infrequent events transiently activate human prefrontal and parietal cortex as measured by functional MRI. J. Neurophysiology 77:1630-1634, 1997.

McKeown, M., Makeig, S., Brown, G., Jung, T-P., Kindermann, S., Bell, Iragui, V. and Sejnowski, T. J., Blind separation of functional magnetic resonance imaging (fMRI) data, Human Brain Mapping, 6:160,18, 1998a.

McKeown, M. J., Humphries, C., Achermann, P., Borbely, A. A. and Sejnowski, T. J.,

A new method for detecting state changes in the EEG: exploratory application to sleep data J. Sleep Res. 7 suppl. 1:48-56, 1998b.

McKeown, M. J., Tzyy-Ping Jung, Scott Makeig, Greg Brown, Sandra S. Kindermann, Te-Won Lee and Terrence J. Sejnowski, Spatially independent activity patterns in functional magnetic resonance imaging data during the Stroop cola-naming task, Proc. Natl. Acad. Sci USA 95:803-810, 1998c.

McKeown, M. J. and Sejnowski, T. J., Independent component analysis of fMRI data: examining the assumptions. Human Brain Mapping 6:368-372, 1998d.

Makeig, S. Auditory event-related dynamics of the EEG spectrum and effects of exposure to tones, Electroencephalogr Clin Neurophysiol, 86:283-293, 1993.

Makeig, S. Toolbox for independent component analysis of psychophysiological data, (World Wide Web publication) www.cnl.salk.edu/˜scott/ica.html, 1997.

Makeig, S. and Galambos, R., The CERP: Event-related perturbations in steady-state responses, in: Brain Dynamics Progress and Perspectives, (pp. 375-400), ed. E. Basar and T. H. Bullock, 1989.

Makeig, S. and Inlow, M., Lapses in alertness: coherence of fluctuations in performance and the EEG spectrum, Electroencephalogr clin Neurophysiol, 86:23-35, 1993.

Makeig, S. and Jung, T-P., Changes in alertness are a principal component of variance in the EEG spectrum, NeuroReport 7:213-216, 1995.

Makeig, S. and T-P. Jung, Tonic, phase, and transient EEG correlates of auditory awareness during drowsiness, Cognitive Brain Research 4:15-25, 1996.

Makeig, S., Bell, A. J., Jung, T-P. and Sejnowski, T. J., “Independent component analysis of electroencephalographic data,” In: D. Touretzky, M. Mozer and M. Hasselmo (Eds). Advances in Neural Information Processing Systems 8:145-151 MIT Press, Cambridge, Mass. 1996.

Makieg, S., Jung, T-P, and Sejnowski, T. J., “Using feedforward neural networks to monitor alertness from changes in EEG correlation and coherence,” In: D. Touretzky, M. Mozer & M. Hasselmo (Eds). Advances in Neural Information Processing Systems 8:931-937 MIT Press, Cambridge, Mass. 1996.

Makeig, S., T-P. Jung, D. Ghahremani, A. J. Bell & T. J. Sejnowski, Blind separation of auditory event-related brain responses into independent components. Proc. Natl. Acad. Sci. USA 94:10979-10984, 1997.

Makeig, S., Westerfield, M., Jung, T-P., Covington, J., Townsend, J., Sejnowski, T. J. and Courchesne, E., Independent components of the late positive event-related potential in a visual spatial attention task, submitted.

Mitra P P, Ogawa S, Hu X, Ugurbil K, The nature of spatiotemporal changes in cerebral hemodynamics as manifested in functional magnetic resonance imaging. Magn Reson Med. 37:511-8, 1997.

Nobre A C, Sebestyen G N, Gitelman D R, Mesulam M M, Frackowiak R S, Frith C D, Functional localization of the system for visuospatial attention using positron emission tomography. Brain 120:515-33, 1997.

Nunez, P. L., Electric Fields of the Brain. New York: Oxford, 1981.

Ogawa S, Tank D W, Menon R, Ellermann J M, Kim S G, Merkle H, Ugurbil K, Intrinsic signal changes accompanying sensory stimulation: functional brain mapping with magnetic resonance imaging. Proc Natl Acad Sci USA 89:5951-5,1992.

Pearlmutter, B. and Parra, L. C. Maximum likelihood blind source separation: a context-sensitive generalization of ICA In: M. C. Mozer, M. I. Jordan and T. Petsche (Eds.), Advances in Neural Information Processing Systems 9:613-619 MIT Press, Cambridge, Mass. 1996.

Sakai K, Hikosaka O, Miyauchi S, Takino R, Sasaki Y, Putz B. Transition of brain activation from frontal to parietal areas in visuomotor sequence learning. J Neurosci 18:1827-40, 1998.

Sahai, Amit and Brent Waters. “Fuzzy identity-based encryption.” In Annual International Conference on the Theory and Applications of Cryptographic Techniques, pp. 457-473. Springer, Berlin, Heidelberg, 2005.

Scherg, M. & Von Cramon, D., Evoked dipole source potentials of the human auditory cortex Electroencephalogr. Clin. Neurophysiol. 65:344-601, 1986.

Tallon-Baudry, C., Bertrand, O., Delpuech, C., & Pemier, J., Stimulus Specificity of Phase-Locked and Non-Phase-Locked 40 Hz Visual Responses in Human. J. Neurosci. 16: 4240-4249, 1996.

Thaker, Darshan D., Diana Franklin, John Oliver, Susmit Biswas, Derek Lockhart, Tzvetan Metodi, and Frederic T. Chong. “Characterization of error-tolerant applications when protecting control data” In Workload Characterization, 2006 IEEE International Symposium on, pp. 142-149. IEEE, 2006.

Tulving E, Markowitsch H J, Craik F E, Habib R, Houle S, Novelty and familiarity activations in PET studies of memory encoding and retrieval. Cereb Cortex 6:71-9, 1996.

Warach, S., J. R Ives, G. Schaug, M. R. Palel, D. G. Darby, V. Thangaraj, R. R. Edelman and D. L. Schomer, EEG-triggered echo-planar functional MRI in epilepsy, Neurology 47: 89-93, 1996.

Principal Component Analysis Principal component analysis (PCA) is a statistical procedure that uses an orthogonal transformation to convert a set of observations of possibly correlated variables into a set of values of linearly uncorrelated variables called principal components. If there are n observations with p variables, then the number of distinct principal components is min(n−1,p). This transformation is defined in such a way that the first principal component has the largest possible variance (that is, accounts for as much of the variability in the data as possible), and each succeeding component in turn has the highest variance possible under the constraint that it is orthogonal to the preceding components. The resulting vectors are an uncorrelated orthogonal basis set PCA is sensitive to the relative scaling of the original variables. PCA is the simplest of the true eigenvector-based multivariate analyses. Often, its operation can be thought of as revealing the internal structure of the data in a way that best explains the variance in the data. If a multivariate dataset is visualized as a set of coordinates in a high-dimensional data space (1 axis per variable), PCA can supply the user with a lower-dimensional picture, a projection of this object when viewed from its most informative viewpoint. This is done by using only the first few principal components so that the dimensionality of the transformed data is reduced. PCA is closely related to factor analysis. Factor analysis typically incorporates more domain specific assumptions about the underlying structure and solves eigenvectors of a slightly different matrix PCA is also related to canonical correlation analysis (CCA). CCA defines coordinate systems that optimally describe the cross-covariance between two datasets while PCA defines a new orthogonal coordinate system that optimally describes variance in a single dataset. See, en.wikepedia.org/wiki/Principal_component_analysis.

A general model for confirmatory factor analysis is expressed as x=α+Λξ+ε. The covariance matrix is expressed as E[(x−μ)(x−μ)′]=ΛΦΛ′+Θ. If residual covariance matrix Θ=0 and correlation matrix among latent factors Φ=I, then factor analysis is equivalent to principal component analysis and the resulting covariance matrix is simplified to Σ=ΛΛ′. When there are p number of variables and all p components (or factors) are extracted, this covariance matrix can alternatively be expressed into Σ=DΛD′, or Σ=λDAD′, where D=n×p orthogonal matrix of eigenvectors, and Λ=λA, p×p matrix of eigenvalues, where λ is a scalar and A is a diagonal matrix whose elements are proportional to the eigenvalues of Σ. The following three components determine the geometric features of the observed data λ parameterizes the volume of the observation, D indicates the orientation, and A represents the shape of the observation.

When population heterogeneity is explicitly hypothesized as in model-based cluster analysis, the observed covariance matrix is decomposed into the following general form ΣkkDkAkDkT,

where λk parameterizes the volume of the kth cluster, Dk indicates the orientation of that cluster, and Ak represents the shape of that cluster. The subscript k indicates that each component (or cluster) can have different volume, shape, and orientation.

Assume a random vector X, taking values in custom characterm, has a mean and covariance matrix of μX and ΣX, respectively. λ12> . . . >λm>0 are ordered eigenvalues of ΣX such that the i-th eigenvalue of ΣX means the i-th largest of them. Similarly, a vector αi is the i-th eigenvector of ΣX when it corresponds to the i-th eigenvalue of ΣX. To derive the form of principal components (PCs), consider the optimization problem of maximizing var[α1TX]=α1TΣXα1, subject to α1Tα1=1. The Lagrange multiplier method is used to solve this question.

L ( α 1 , ϕ 1 ) = α 1 T X α 1 + ϕ 1 ( α 1 T α 1 - 1 ) L α 1 = 2 X α 1 + 2 ϕ 1 α 1 = 0 X α 1 = - ϕ 1 α 1 var [ α 1 T X ] = - ϕ 1 α 1 T α 1 = - ϕ 1 .

Because −ϕ1 is the eigenvalue of ΣX, with α1 being the corresponding normalized eigenvector, var[α1TX] is maximized by choosing α1 to be the first eigenvector of ΣX. In this case, z11TX is named the first PC of X, α1 is the vector of coefficients for z1, and var(z1)=λ1.

To find the second PC, z22TX, we need to maximize var[α2TX]=α2TΣXα2 subject to z2 being uncorrelated with z1. Because cov(α1TX,α2TX)=0⇒α1TΣXα2=0⇒α1Tα2=0, this problem is equivalency set as maximizing α2TΣXα2, subject to α1Tα2=0, and α2Tα2=1. We still make use of the Lagrange multiplier method.

L ( α 2 , ϕ 1 , ϕ 2 ) = α 2 T X α 2 + ϕ 1 α 1 T α 2 + ϕ 2 ( α 2 T α 2 - 1 ) L α 2 = 2 X α 2 + ϕ 1 α 1 + 2 ϕ 2 α 2 = 0 α 1 T ( 2 X α 2 + ϕ 1 α 1 + 2 ϕ 2 α 2 ) = 0 ϕ 1 = 0 X α 2 = - ϕ 2 α 2 α 2 T X α 2 = - ϕ 2 .

Because −ϕ2 is the eigenvalue of ΣX, with α2 being the corresponding normalized eigenvector, var[α2TX] is maximized by choosing α2 to be the second eigenvector of ΣX. In this case, z22TX is named the second PC of X, α2 is the vector of coefficients for z2, and var(z2)=λ2. Continuing in this way, it can be shown that the i-th PC ziiTX is constructed by selecting αi to be the i-th eigenvector of ΣX, and has variance of λi. The key result in regards to PCA is that the principal components are the only set of linear functions of original data that are uncorrelated and have orthogonal vectors of coefficients.

For any positive integer p≤m, let B=[β1, β2, . . . , βp] be an real m×p matrix with orthonormal columns, i.e., βiTβjij, and Y=BTX. Then the trace of covariance matrix of Y is maximized by taking B=[α1, α2, . . . , αp], where αi is the i-th eigenvector of ΣX. Because ΣX is symmetric with all distinct eigenvalues, so {α1, α2, . . . , αm} is an orthonormal basis with αi being the i-th eigenvector of ΣX, and we can represent the columns of B as

β i = j = 1 m c ji α j ,
i=1, . . . , p, So we have B=PC, where P=[α1, . . . , αm], C={cij} is an m×p matrix. PTΣXP=Λ, with A being a diagonal matrix whose k-th diagonal element is λk, and the covariance matrix of Y is,
ΣY=BTΣXB=CTPTΣXPC=CTΛC=λ1c1c1T+ . . . +λmcmcmT

where ciT is the i-th row of C. So,

trace ( Y ) = i = 1 m λ i trace ( c i c i T ) = i = 1 m λ i trace ( c i T c i ) = i = 1 m λ i c i T c i = i = 1 m ( j = 1 p c ij 2 ) λ i .

Because CTC=BTPPTB=BTB=1, so

trace ( C T C ) = i = 1 m j = 1 p c ij 2 = p ,
and the columns of C are orthonormal. By the Gram-Schmidt method, C can expand to D, such that D has its columns as an orthonormal basis of custom characterm and contains C as its first P columns. D is square shape, thus being an orthogonal matrix and having its rows as another orthonormal basis of custom characterm. One row of C is a part of one row of D, so

j = 1 p c ij 2 1 ,
i=1, . . . , m. Considering the constraints

j = 1 p c ij 2 1 , i = 1 m j = 1 p c ij 2 = p
and the objective

i = 1 m ( j = 1 p c ij 2 ) λ i .
We derive that trace(ΣY) is maximized if

j = 1 p c ij 2 = 1
for i=1, . . . , p, and

j = 1 p c ij 2 = 0
for i=p+1, . . . , m. When B=[α1, α2, . . . , αp], straightforward calculation yields that C is an all-zero matrix except cii=1, i=1, . . . , p. This fulfills the maximization condition. Actually, by taking B=[γ1, γ2, . . . , γp], where {γ1, γ2, . . . , γp} is any orthonormal basis of the subspace of span{α1, α2, . . . , αp}, the maximization condition is also satisfied, yielding the same trace of covariance matrix of Y.

Suppose that we wish to approximate the random vector X by its projection onto a subspace spanned by columns of B, where B=[β1, β2, . . . , βp] is a real m×p matrix with orthonormal columns, i.e., βiTβjij. If σi2 is the residual variance for each component of X, then

i = 1 m σ i 2
is minimized if B=[α1, α2, . . . , αp], where {α1, α2, . . . , αp} are the first p eigenvectors of ΣX. In other words, the trace of covariance matrix of X−BBTX is minimized if B=[α1, α2, . . . , αp]. When E(X)=0, which is a commonly applied preprocessing step in data analysis methods, this property is saying that E∥X−BBT2 is minimized if B=[α1, α2, . . . , αp].

The projection of a random vector X onto a subspace spanned by columns of B is {circumflex over (X)}=BBTX. Then the residual vector is ε=X−BBTX, which has a covariance matrix

ɛ = ( I - BB T ) X ( I - BB ) T . Then , i = 1 m σ i 2 = trace ( ɛ ) = trace ( X - X BB T - BB T X + BB T X BB T ) .

Also, we know:
trace(ΣXBBT)=trace(BBTΣX)=trace(BTΣXB)
trace(BBTΣXBBT)=trace(BTΣXBBTB)=trace(BTΣXB)

The last equation comes from the fact that B has orthonormal columns. So,

i = 1 m σ i 2 = trace ( X ) - trace ( B T X B ) .

To minimize

i = 1 m σ i 2 ,
it suffices to maximize trace(BTΣXB). This can be done by choosing B=[α1, α2, . . . , αp], where {α1, α2, . . . , αp} are the first p eigenvectors of ΣX, as above.

See, Pietro Amenta, Luigi D'Ambra, “Generalized Constrained Principal Component Analysis with External Information,” (2000). We assume that data on K sets of explanatory variables and S criterion variables of n statistical units are collected in matrices Xk (k=1, . . . , K) and Ys (s=1, . . . , S) of orders (n×p1), . . . , (n×pK) and (n×q1), . . . , (n×qS), respectively. We suppose, without loss of generality, identify matrices for the metrics of the spaces of variables of Xk and Ys with Dn=diag(1/n), weight matrix of statistical units. We assume, moreover, that Xk's and Ys's are centered as to the weights Dn.

Let X=[X1| . . . |XK] and Y=[Y1| . . . |YS], respectively, be K and S matrices column linked of orders (n×Σkpk) and (n×Σsqs). Let be, also, WY=YY′ while we denote vk the coefficients vector (pk,1) of the linear combination for each Xk such that zk=Xkvk. Let Ck be the matrix of dimension pk×m(m≤pk), associated to the external information explanatory variables of set k.

Generalized CPCA (GCPCA) (Amenta, D'Ambra, 1999) with external information consists in seeking for K coefficients vectors vk (or, in same way, K linear combinations zk) subject to the restriction C′kvk=0 simultaneously, such that

{ max i = 1 K j = 1 K Y X i v i , Y X j v j with the constraints k = 1 K X k v k 2 = 1 k = 1 K C k v k = 0 ( 1 )

or, in equivalent way,

{ max v ( A A ) v with the constraints v Bv = 1 C v = 0 or { max f B - 0.5 A AB - 0.5 with the constraints f f = 1 C v = 0

where A=Y′X, B=diag(X′1X1, . . . , X′KXK), C′=[C1| . . . |C′k], v′=(v1′| . . . |vk′) and f=B0.5v, with

A A = [ X 1 YY X 1 X 1 YY X K X K YY X 1 X k YY X k ] .

The constrained maximum problem turns out to be an extension of criterion supΣk∥zk2=1ΣiΣkcustom characterzi,zkcustom character (Sabatier, 1993) with more sets of criterion variables with external information. The solution of this constrained maximum problem leads to solve the eigen-equation
(PX−PXB−1C)WYg=λg

where g=Xv, PX−PXB−1Ck=1K(PXk−PXk(X′kXk)−1Ck) is the oblique projector operator associated to the direct sum decomposition of custom charactern
custom charactern=Im(PX−PXB−1C){dot over (⊕)}Im(PC){dot over (⊕)}Ker(PX)

with PXk=k(X′kXk)−1X′k and PC=C(C′B−1C)−1C′B−1, respectively, /and B−1 orthogonal projector operators onto the subspaces spanned by the columns of matrices Xk and C. Furthermore, PXB−1C=XB−1C(C′B−1C)−1C′B−1X′ is the orthogonal projector operator onto the subspace spanned the columns of the matrix XB−1C. Starting from the relation
(PXk−PXk(X′kXk)−1Ck)WYg=λXkvk

(which is obtained from the expression (I−PC)X′WYg=λBv) the coefficients vectors vk and the linear combinations zkXkvk maximizing (1) can be given by the relations

v k = 1 λ ( X k X k ) - 1 ( I - P C k ) X k W Y Xv and z k = 1 λ ( P X k - P X k ( X k X k ) - 1 C k ) W Y Xv ,
respectively.

The solution eigenvector g can be written, as sum of the linear combinations zk: g=ΣkXkvk. Notice that the eigenvalues associated to the eigen-system are, according to the Sturm theorem, lower or equal than those of GCPCA eigen-system: Σk=1KPXkWYg=λg. See:

Amenta P., D'Ambra L. (1994) Analisi non Simmetrica delle Corrispondenze Multiple con Vincoli Lineari. Atti S.I.S. XXXVII Sanremo, Aprile 1994.

Amenta P., D'Ambra L. (1996) L'Analisi in Componenti Principali in rapporto ad un sottospazio di riferimento con infbrmazioni esteme, Quademi del D.M.Q.T.E., Universitadi Pescara, n. 18.

Amenta P., D'Ambra L. (1999) Generalized Constrained Principal Component Analysis. Atti Riunione Scientifica del Gruppo di Classificazione dell'IFCS su “Classificazione e Analisi dei Dati”, Roma.

D'Ambra L., Lauro N. C. (1982) Analisi in componenti principali in rapporto ad un sottospazio di riferimento, Rivista di Statistica Applicata, n.1, vol. 15.

D'Ambra L., Sabatier R., Amenta P. (1998) Analisi fattoriale delle matrici a tre vie: sintesi e nuovi approcci, (invited lecture) Atti XXXIX Riunione SIS.

Huon de Kermadec F., Durand J. F., Sabatier R. (1996) Comparaison de methodes de regression pour l'étude des liens entre données hédoniques, in Third Sensometrics Meeting, E.N.T.I.A.A., Nantes.

Huon de Kermadec F., Durand J. F., Sabatier R. (1997) Comparison between linear and nonlinear PLS methods to explain overall liking from sensory characteristics, Food Quality and Preference, 8, n. 5/6.

Kiers H. A. L. (1991) Hierarchical relations among three way methods Psychometrika, 56.

Kvalheim O. M. (1988) A partial least squares approach to interpretative analysis of multivariate analysis, Chemometrics and Intelligent Laboratory System, 3.

MacFie H. J. H., Thomson D. M. H. (1988) Preference mapping and multidimensional scaling methods, in: Sensory Analysis of Foods. Elsevier Applied Science, London.

Sabatier R. (1993) Critéres et contraintes pour l'ordination simultanée de K tableaux, Biométrie et Environemerrt, Masson, 332.

Schlich P. (1995) Preference mapping: relating consumer preferences to sensory or instrumental measurements, in: Bioflavour, INRA Dijon.

Wold S., Geladi P., Esbensen K., Ohman J. (1987) Multi-way principal components and PLS-analysis, J. of Chemometrics, vol. 1.

Spatial Principal Component Analysis (Spatial PCA) Let J(t,i;α,s) be the current density in voxel i, as estimated by LORETA in condition α at t time-frames after stimulus onsetfor subjects. Let area:Voxel→fBA be a function, which assigns to each voxel i∈Voxel the corresponding fBA b∈fBA. In a first preprocessing step, for each subject s, the value of the current density averaged over each fBA is calculated:

x ( t , b ; α , s ) = 1 N b i b J ( t , i ; α , s ) ( 4 )

where Nb is the number of voxels in the fBA b, in condition α for subject s.

In the second analysis stage, the mean current density x(t,b;α,s) from each fBA b, for every subject s and condition α was subjected to spatial PCA analysis of the correlation matrix and varimax rotation

The spatial PCA uses the above-defined fBAs as variables sampled along the time epoch for which EEG has been sampled (e.g., 0-1000 ms; 512 time-frames), and the inverse solution estimated. Spatial matrices (e.g., each matrix was sized b×t=36×512 elements) for every subject and condition may be collected, and subjected to PCA analyses, including the calculation of the covariance matrix; eigenvalue decomposition and varimax rotation, in order to maximize factor loadings. In other words, the spatial PCA analysis approximates the mean current density for each subject in each condition as

x ( t ; α , s ) x 0 ( α , s ) + k c k ( t ) x k ( α , s ) , ( 5 )

where here x(t;α,s)∈R36 is a vector, which denotes the time-dependent activation of the fBAs, x0(α,s) is their mean activation, and xk(α,s) and ck are the principal components and their corresponding coefficients (factor loadings) as computed using the principal component analysis. See:

Arzouan Y, Goldstein A, Faust M. Brainwaves are stethoscopes: ERP correlates of novel metaphor comprehension. Brain Res 2007; 1160: 69-81.

Arzouan Y, Goldstein A, Faust M. Dynamics of hemispheric activity during metaphor comprehension: electrophysiological measures. NeuroImage 2007; 36: 222-231.

Chapman R M, McCrary J W. EP component identification and measurement by principal components analysis. Brain and cognition 1995; 27: 288-310.

Dien J, Frishkoff G A Cerbone A, Tucker D M. Parametric analysis of event-related potentials in semantic comprehension: evidence for parallel brain mechanisms. Brain research 2003; 15: 137-153.

Dien J, Frishkoff G A. Principal components analysis of event-related potential datasets. In: Handy T (ed). Event-Related Potentials: A Methods Handbook. Cambridge, Mass. MIT Press; 2004.

Potts G F, Dien J, Hartry-Speiser A L, McDougal L M, Tucker D M. Dense sensor array topography of the event-related potential to task-relevant auditory stimuli. Electroencephalography and clinical neurophysiology 1998; 106: 444-456.

Rosler F, Manzey D. Principal components and varimax-rotated components in event-related potential research: some remarks on their interpretation. Biological psychology 1981; 13: 3-26.

Ruchkin D S, McCalley M G, Qaser E M. Event related potentials and time estimation. Psychophysiology 1977; 14: 451-455.

Spencer K M, Dien J, Donchin E. Spatiotemporal analysis of the late ERP responses to deviant stimuli. Psychophysiology 2001; 38: 343-358.

Squires K C, Squires N K, Hillyard S A. Decision-related cortical potentials during an auditory signal detection task with cued observation intervals. Journal of experimental psychology 1975; 1: 268-279.

van Boxtel A, Boelhouwer A J, Bos A R. Optimal EMG signal bandwidth and interelectrode distance for the recording of acoustic, electrocutaneous, and photic blink reflexes. Psychophysiology 1998; 35: 690-697.

download.lww.com/wolterskluwer.com/WNR_1_1_2010_03_22_ARZY_1_SDC1.doc.

Nonlinear Dimensionality Reduction High-dimensional data, meaning data that requires more than two or three dimensions to represent, can be difficult to interpret. One approach to simplification is to assume that the data of interest lie on an embedded non-linear manifold within the higher-dimensional space. If the manifold is of low enough dimension, the data can be visualized in the low-dimensional space. Non-linear methods can be broadly classified into two groups: those that provide a mapping (either from the high-dimensional space to the low-dimensional embedding or vice versa), and those that just give a visualization. In the context of ML, mapping methods may be viewed as a preliminary feature extraction step, after which pattern recognition algorithms are applied. Typically, those that just give a visualization are based on proximity data—that is, distance measurements. Related Linear Decomposition Methods include Independent component analysis (ICA), Principal component analysis (PCA) (also called Karhunen-Loève transform—KLT), Singular value decomposition (SVD), and Factor analysis.

The self-organizing map (SOM, also called Kohonen map) and its probabilistic variant generative topographic mapping (GTM) use a point representation in the embedded space to form a latent variable model based on a non-linear mapping from the embedded space to the high-dimensional space. These techniques are related to work on density networks, which also are based around the same probabilistic model.

Principal curves and manifolds give the natural geometric framework for nonlinear dimensionality reduction and extend the geometric interpretation of PCA by explicitly constructing an embedded manifold, and by encoding using standard geometric projection onto the manifold. How to define the “simplicity” of the manifold is problem-dependent, however, it is commonly measured by the intrinsic dimensionality and/or the smoothness of the manifold. Usually, the principal manifold is defined as a solution to an optimization problem. The objective function includes a quality of data approximation and some penalty terms for the bending of the manifold. The popular initial approximations are generated by linear PCA Kohonen's SOM or autoencoders. The elastic map method provides the expectation-maximization algorithm for principal manifold learning with minimization of quadratic energy functional at the “maximization” step.

An autoencoder is a feed-forward neural network which is trained to approximate the identity function. That is, it is trained to map from a vector of values to the same vector. When used for dimensionality reduction purposes, one of the hidden layers in the network is limited to contain only a small number of network units. Thus, the network must learn to encode the vector into a small number of dimensions and then decode it back into the original space. Thus, the first half of the network is a model which maps from high to low-dimensional space, and the second half maps from low to high-dimensional space. Although the idea of autoencoders is quite old, training of deep autoencoders has only recently become possible through the use of restricted Boltzmann machines and stacked denoising autoencoders. Related to autoencoders is the NeuroScale algorithm, which uses stress functions inspired by multidimensional scaling and Sammon mappings (see below) to learn a non-linear mapping from the high-dimensional to the embedded space. The mappings in NeuroScale are based on radial basis function networks.

Gaussian process latent variable models (GPLVM) are probabilistic dimensionality reduction methods that use Gaussian Processes (GPs) to find a lower dimensional non-linear embedding of high dimensional data. They are an extension of the Probabilistic formulation of PCA. The model is defined probabilistically and the latent variables are then marginalized and parameters are obtained by maximizing the likelihood. Like kernel PCA they use a kernel function to form a nonlinear mapping (in the form of a Gaussian process). However, in the GPLVM the mapping is from the embedded(latent) space to the data space (like density networks and GTM) whereas in kernel PCA it is in the opposite direction. It was originally proposed for visualization of high dimensional data but has been extended to construct a shared manifold model between two observation spaces. GPLVM and its many variants have been proposed specially for human motion modeling, e.g., back constrained GPLVM, GP dynamic model (GPDM), balanced GPDM (B-GPDM) and topologically constrained GPDM. To capture the coupling effect of the pose and gait manifolds in the gait analysis, a multi-layer joint gait-pose manifolds was proposed.

Curvilinear component analysis (CCA) looks for the configuration of points in the output space that preserves original distances as much as possible while focusing on small distances in the output space (conversely to Sammon's mapping which locus on small distances in original space). It should be noticed that CCA as an iterative learning algorithm, actually starts with focus on large distances (like the Sammon algorithm), then gradually change focus to small distances. The small distance information will overwrite the large distance information, if compromises between the two have to be made. The stress function of CCA is related to a sum of right Bregman divergences. Curvilinear distance analysis (CDA) trains a self-organizing neural network to fit the manifold and seeks to preserve geodesic distances in its embedding. It is based on Curvilinear Component Analysis (which extended Sammon's mapping), but uses geodesic distances instead. Diffeomorphic Dimensionality Reduction or Diffeomap learns a smooth diffeomorphic mapping which transports the data onto a lower-dimensional linear subspace. The method solves for a smooth time indexed vector field such that flows along the field which start at the data points will end at a lower-dimensional linear subspace, thereby attempting to preserve pairwise differences under both the forward and inverse mapping.

Perhaps the most widely used algorithm for manifold learning is Kernel principal component analysis (kernel PCA). It is a combination of Principal component analysis and the kernel trick PCA begins by computing the covariance matrix of the M×n Matrix X. It then projects the data onto the first k eigenvectors of that matrix. By comparison, KPCA begins by computing the covariance matrix of the data after being transformed info a higher-dimensional space. It then projects the transformed data onto the first k eigenvectors of that matrix, just like PCA It uses the kernel trick to factor away much of the computation, such that the entire process can be performed without actually computing ϕ(x). Of course ϕ must be chosen such that it has a known corresponding kernel.

The Fourier transform (FT) decomposes a function of time (a signal) into the frequencies that make it up. The Fourier transform of a function of time is itself a complex-valued function of frequency, whose absolute value represents the amount of that frequency present in the original function, and whose complex argument is the phase offset of the basic sinusoid in that frequency. The Fourier transform is called the frequency domain representation of the original signal. The term Fourier transform refers to both the frequency domain representation and the mathematical operation that associates the frequency domain representation to a function of time. The Fourier transform is not limited to functions of time, but in order to have a unified language, the domain of the original function is commonly referred to as the time domain. For many functions of practical interest, one can define an operation that reverses this: the inverse Fourier transformation, also called Fourier synthesis, of a frequency domain representation combines the contributions of all the different frequencies to recover the original function of time. See, en.wikipedia.org/wiki/Fourier_transform.

The Fourier transform of a finite Borel measure μ on custom charactern is given by: {circumflex over (μ)}(ζ)=custom charactere−2πixζdμ. This transform continues to enjoy many of the properties of the Fourier transform of integrable functions. One notable difference is that the Riemann-Lebesgue lemma fails for measures. In the case that dμ=f(x)dx, then the formula above reduces to the usual definition for the Fourier transform of f. In the case that μ is the probability distribution associated to a random variable X, the Fourier-Stieltjes transform is closely related to the characteristic function, but the typical conventions in probability theory take eixζ instead of e−2πixζ. In the case when the distribution has a probability density function this definition reduces to the Fourier transform applied to the probability density function, again with a different choice of constants. The Fourier transform may be used to give a characterization of measures. Bochner's theorem characterizes which functions may arise as the Fourier-Stieltjes transform of a positive measure on the circle. Furthermore, the Dirac delta function, although not a function, is a finite Borel measure. Its Fourier transform is a constant function (whose specific value depends upon the form of the Fourier transform used). See Pinsky, Mark (2002), Introduction to Fourier Analysis and Wavelets, Brooks/Cole, ISBN 978-0-534-376604; Katznelson, Yitzhak (1976), An Introduction to Harmonic Analysis, Dover, ISBN 978-0-486-63331-2.

The Fourier transform is also a special case of Gelfand transform. In this particular context it is closely related to the Pontryagin duality map. Given an abelian locally compact Hausdorff topological group G, as before we consider space L1(G), defined using a Haar measure. With convolution as multiplication, L1(G) is an abelian Banach algebra. Taking the completion with respect to the largest possibly C*-norm gives its enveloping C*-algebra, called the group C*-algebra C*(G) of G. (Any C*-norm on L1(G) is bounded by the L1 norm, therefore their supremum exists.) 8 is the involution operator. Given any abelian C*-algebra A, the Gelfand transform gives an isomorphism between A and C0(A{circumflex over ( )}), where A{circumflex over ( )} is the multiplicative linear functionals, i.e. one-dimensional representations, on A with the weak-*topology. The multiplicative linear functionals of C*(G), after suitable identification, are exactly the characters of G, and the Gelfand transform, when restricted to the dense subset L1(G) is the Fourier-Pontryagin transform.

The Laplace transform is very similar to the Fourier transform. While the Fourier transform of a function is a complex function of a real variable (frequency), the Laplace transform of a function is a complex function of a complex variable. Laplace transforms are usually restricted to functions of t with t≥0. A consequence of this restriction is that the Laplace transform of a function is a holomorphic function of the variable s. The Laplace transform of a distribution is generally a well-behaved function. As a holomorphic function, the Laplace transform has a power series representation. This power series expresses a function as a linear superposition of moments of the function. The Laplace transform is invertible on a large class of functions. The inverse Laplace transform takes a function of a complex variable s (often frequency) and yields a function of a real variable t (time). Given a simple mathematical or functional description of an input or output to a system, the Laplace transform provides an alternative functional description that often simplifies the process of analyzing the behavior of the system, or in synthesizing a new system based on a set of specifications. So, for example, Laplace transformation from the time domain to the frequency domain transforms differential equations info algebraic equations and convolution into multiplication. See, en.wikipedia.org/wiki/Laplace_transform.

The short-time Fourier transform (STFT), is a Fourier-related transform used to determine the sinusoidal frequency and phase content of local sections of a signal as it changes overtime. In practice, the procedure for computing STFTs is to divide a longer time signal into shorter segments of equal length and then compute the Fourier transform separately on each shorter segment. This reveals the Fourier spectrum on each shorter segment. One then usually plots the changing spectra as a function of time. The signal may be windowed using, e.g., a Hann window or a Gaussian window. See, en.wikipedia.org/wiki/Short-time_Fourier_transform.

The fractional Fourier transform (FRFT), is a generalization of the classical Fourier transform. The FRFT of a signal can also be interpreted as a decomposition of the signal in terms of chirps. The FRFT can be used to define fractional convolution, correlation, and other operations, and can also be further generalized into the linear canonical transformation (LCT). See: en.wikipedia.org/wiki/Fractional_Fourier_transform.

Almeida, Luis B. “The fractional Fourier transform and time-frequency representations.” IEEE Transactions on signal processing 42, no. 11 (1994): 3084-3091.

Bailey, David H., and Paul N. Swarztrauber. “The fractional Fourier transform and applications.” SIAM review 33, no. 3 (1991): 389-404.

Candan, Cagatay, M. Alper Kutay, and Haldun M. Ozaktas. “The discrete fractional Fourier transform.” IEEE Transactions on signal processing 48, no. 5 (2000): 1329-1337.

Lohmann, Adolf W. “Image rotation, Wigner rotation, and the fractional Fourier transform.” JOSA A10, no. 10 (1993): 2181-2186.

Ozaktas, Haldun M., and David Mendlovic. “Fourier transforms of fractional order and their optical interpretation.” Optics Communications 101, no. 34 (1993): 163-169.

Ozaktas, Haldun M., and M. Alper Kutay. “The fractional Fourier transform.” In Control Conference (ECC), 2001 European, pp. 1477-1483. IEEE, 2001.

Ozaktas, Haldun M., Orhan Arikan, M. Alper Kutay, and Gozde Bozdagt. “Digital computation of the fractional Fourier transform.” IEEE Transactions on signal processing 44, no. 9 (1996): 2141-2150.

Pei, Soo-Chang, Min-Hung Yeh, and Chien-Cheng Tseng. “Discrete fractional Fourier transform based on orthogonal projections.” IEEE Transactions on Signal Processing 47, no. 5 (1999): 1335-1348.

Qi, Lin, Ran Tao, Siyong Zhou, and Yue Wang. “Detection and parameter estimation of multicomponent LFM signal based on the fractional Fourier transform.” Science in China series F: information sciences 47, no. 2 (2004): 184.

Tao, Ran, Yan-Lei Li, and Yue Wang. “Short-time fractional Fourier transform and its applications.” IEEE Transactions on Signal Processing 58, no. 5 (2010): 2568-2580.

Xia, Xiang-Gen. “On bandlimited signals with fractional Fourier transform.” IEEE Signal Processing Letters 3, no. 3 (1996): 72-74.

Zayed, Ahmed I. “A convolution and product theorem for the fractional Fourier transform.” IEEE Signal processing letters 5, no. 4 (1998): 101-103.

Zayed, Ahmed I. “On the relationship between the Fourier and fractional Fourier transforms.” IEEE signal processing letters 3, no. 12(1996): 310-311.

Laplacian Eigenmaps, (also known as Local Linear Eigenmaps, LLE) are special cases of kernel PCA performed by constructing a data-dependent kernel matrix KPCA has an internal model, so it can be used to map points onto its embedding that were not available at training time. Laplacian Eigenmaps uses spectral techniques to perform dimensionality reduction. This technique relies on the basic assumption that the data lies in a low-dimensional manifold in a high-dimensional space. This algorithm cannot embed out of sample points, but techniques based on Reproducing kernel Hilbert space regularization exist for adding this capability. Such techniques can be applied to other nonlinear dimensionality reduction algorithms as well. Traditional techniques like principal component analysis do not consider the intrinsic geometry of the data Laplacian eigenmaps builds a graph from neighborhood information of the data set. Each data point serves as a node on the graph and connectivity between nodes is governed by the proximity of neighboring points (using e.g. the k-nearest neighbor algorithm). The graph thus generated can be considered as a discrete approximation of the low-dimensional manifold in the high-dimensional space. Minimization of a cost function based on the graph ensures that points close to each other on the manifold are mapped close to each other in the low-dimensional space, preserving local distances. The eigenfunctions of the Laplace-Beltrami operator on the manifold serve as the embedding dimensions, since under mild conditions this operator has a countable spectrum that is a basis for square integrable functions on the manifold (compare to Fourier series on the unit circle manifold). Attempts to place Laplacian eigenmaps on solid theoretical ground have met with some success, as under certain nonrestrictive assumptions, the graph Laplacian matrix has been shown to converge to the Laplace-Beltrami operator as the number of points goes to infinity. In classification applications, low dimension manifolds can be used to model data classes which can be defined from sets of observed instances. Each observed instance can be described by two independent factors termed ‘content’ and ‘style’, where ‘content’ is the invariant factor related to the essence of the class and ‘style’ expresses variations in that class between instances. Unfortunately, Laplacian Eigenmaps may fail to produce a coherent representation of a class of interest when training data consist of instances varying significantly in terms of style. In the case of classes which are represented by multivariate sequences, Structural Laplacian Eigenmaps has been proposed to overcome this issue by adding additional constraints within the Laplacian Eigenmaps neighborhood information graph to better reflect the intrinsic structure of the class. More specifically, the graph is used to encode both the sequential structure of the multivariate sequences and, to minimize stylistic variations, proximity between data points of different sequences or even within a sequence, if it contains repetitions. Using dynamic time warping, proximity is detected by finding correspondences between and within sections of the multivariate sequences that exhibit high similarity.

Like LLE, Hessian LLE is also based on sparse matrix techniques. It tends to yield results of a much higher quality than LLE. Unfortunately, it has a very costly computational complexity, so it is not well-suited for heavily sampled manifolds. It has no internal model. Modified LLE (MLLE) is another LLE variant which uses multiple weights in each neighborhood to address the local weight matrix conditioning problem which leads to distortions in LLE maps. MLLE produces robust projections similar to Hessian LLE, but without the significant additional computational cost.

Manifold alignment takes advantage of the assumption that disparate data sets produced by similar generating processes will share a similar underlying manifold representation. By learning projections from each original space to the shared manifold, correspondences are recovered and knowledge from one domain can be transferred to another. Most manifold alignment techniques consider only two data sets, but the concept extends to arbitrarily many initial data sets. Diffusion maps leverages the relationship between heat diffusion and a random walk (Markov Chain); an analogy is drawn between the diffusion operator on a manifold and a Markov transition matrix operating on functions defined on the graph whose nodes were sampled from the manifold. Relational perspective map is a multidimensional scaling algorithm. The algorithm finds a configuration of data points on a manifold by simulating a multi-particle dynamic system on a closed manifold, where data points are mapped to particles and distances (or dissimilarity) between data points represent a repulsive force. As the manifold gradually grows in size the multi-particle system cools down gradually and converges to a configuration that reflects the distance information of the data points. Local tangent space alignment (LTSA) is based on the intuition that when a manifold is correctly unfolded, all of the tangent hyperplanes to the manifold will become aligned. It begins by computing the k-nearest neighbors of every point. It computes the tangent space at every point by computing the d-first principal components in each local neighborhood. It then optimizes to find an embedding that aligns the tangent spaces. Local Multidimensional Scaling performs multidimensional scaling in local regions, and then uses convex optimization to fit all the pieces together.

Maximum Variance Unfolding was formerly known as Semidefinite Embedding. The intuition for this algorithm is that when a manifold is properly unfolded, the variance over the points is maximized. This algorithm also begins by finding the k-nearest neighbors of every point. It then seeks to solve the problem of maximizing the distance between all non-neighboring points, constrained such that the distances between neighboring points are preserved. Nonlinear PCA (NLPCA) uses backpropagation to train a multi-layer perception (MLP) to fit to a manifold. Unlike typical MLP training, which only updates the weights, NLPCA updates both the weights and the inputs. That is, both the weights and inputs are treated as latent values. After training, the latent inputs are a low-dimensional representation of the observed vectors, and the MLP maps from that low-dimensional representation to the high-dimensional observation space. Manifold Sculpting uses graduated optimization to find an embedding. Like other algorithms, it computes the k-nearest neighbors and tries to seek an embedding that preserves relationships in local neighborhoods. It slowly scales variance out of higher dimensions, while simultaneously adjusting points in lower dimensions to preserve those relationships.

Ruffini (2015) discusses Multichannel transcranial current stimulation (tCS) systems that offer the possibility of EEG-guided optimized, non-invasive brain stimulation. A tCS electric field realistic brain model is used to create a forward “lead-field” matrix and, from that, an EEG inverter is employed for cortical mapping. Starting from EEG, 2D cortical surface dipole fields are defined that could produce the observed EEG electrode voltages.

Schestatsky et al. (2017) discuss transcranial direct current stimulation (DCS), which stimulates through the scalp with a constant electric current that induces shifts in neuronal membrane excitability, resulting in secondary changes in cortical activity. Although tDCS has most of its neuromodulator effects on the underlying cortex, tDCS effects can also be observed in distant neural networks. Concomitant EEG monitoring of the effects of tDCS can provide valuable information on the mechanisms of tDCS. EEG findings can be an important surrogate marker for the effects of tDCS and thus can be used to optimize its parameters. This combined EEG-tDCS system can also be used for preventive treatment of neurological conditions characterized by abnormal peaks of cortical excitability, such as seizures. Such a system would be the basis of a non-invasive closed-bop device. tDCS and EEG can be used concurrently. See:

Albert, Jacobo, Sara López-Martin, José Antonio Hinojosa, and Luis Carretié. “Spatiotemporal characterization of response inhibition.” Neuroimage 76 (2013): 272-281.

Arzouan Y, Goldstein A, Faust M. Brainwaves are stethoscopes: ERP correlates of novel metaphor comprehension. Brain Res 2007; 1160: 69-81.

Arzouan Y, Goldstein A, Faust M. Dynamics of hemispheric activity during metaphor comprehension: electrophysiological measures. NeuroImage 2007; 36: 222-231.

Arzy, Shahar, Yossi Arzouan, Esther Adi-Japha, Sorin Solomon, and Olaf Blanke. “The ‘intrinsic’ system in the human cortex and self-projection: a data driven analysis.” Neuroreport 21, no. 8 (2010): 569-574.

Bao, Xuecai, Jinli Wang, and Jianfeng Hu. “Method of individual identification based on electroencephalogram analysis.” In New Trends in Information and Service Science, 2009. NISS'09. International Conference on, pp. 390-393. IEEE, 2009.

Bhattacharya, Joydeep. “Complexity analysis of spontaneous EEG.” Acta neurobiobgiae experimentalis 60, no. 4 (2000): 495-502.

Chapman R M, McCrary J W. EP component identification and measurement by principal components analysis. Brain and cognition 1995; 27: 288-310.

Clementz, Brett A, Stefanie K. Barber, and Jacqueline R. Dzau. “Knowledge of stimulus repetition affects the magnitude and spatial distribution of low-frequency event-related brain potentials.” Audiology and Neurotology 7, no. 5 (2002): 303-314.

Dien J, Frishkoff G A, Cerbone A, Tucker D M. Parametric analysis of event-related potentials in semantic comprehension: evidence for parallel brain mechanisms. Brain research 2003; 15: 137-153.

Dien J, Frishkoff G A. Principal components analysis of event-related potential datasets. In: Handy T (ed). Event-Related Potentials: A Methods Handbook Cambridge, Mass. MIT Press; 2004.

Elbert, T. “IIIrd Congress of the Spanish Society of Psychophysiology.” Journal of Psychophysiology 17 (2003): 39-53.

Groppe, David M., Scott Makeig, Marta Kutas, and S. Diego. “Independent component analysis of event-related potentials.” Cognitive science online 6, no. 1 (2008): 1-44.

Have, Mid-Ventrolateral Prefrontal Cortex “Heschl's Gyrus, Posterior Superior Temporal Gyrus.” J Neurophysiol 97 (2007): 2075-2082.

Hinojosa, J. A, J. Albert S. López-Martin, and L. Carretié. “Temporospatial analysis of explicit and implicit processing of negative content during word comprehension.” Brain and cognition 87 (2014): 109-121.

Jarchi, Delaram, Saeid Sanei, Jose C. Principe, and Bahador Makkiabadi. “A new spatiotemporal filtering method for single-trial estimation of correlated ERP subcomponents.” IEEE Transactions on Biomedical Engineering 58, no. 1 (2011): 132-143.

John, Erwin Roy. “A field theory of consciousness.” Consciousness and cognition 10, no. 2(2001): 184-213.

Johnson, Mark H., Michelle de Haan, Andrew Oliver, Warwick Smith, Haralambos Hatzakis, Leslie A Tucker, and Gergely Csibra “Recording and analyzing high-density event-related potentials with infants using the Geodesic Sensor Net.” Developmental Neuropsychology 19, no. 3 (2001): 295-323.

Jung, Tzyy-Ping, and Scott Makeig. “Mining Electroencephalographic Data Using Independent Component Analysis.” EEG Journal (2003).

Kashyap, Rajan. “Improved localization of neural sources and dynamical causal modelling of latency-corrected event related brain potentials and applications to face recognition and priming.” (2015).

Klawohn, Julia, Anja Riesel, Rosa Grützmann, Norbert Kathmann, and Tanja Endrass. “Performance monitoring in obsessive-compulsive disorder. A temporo-spatial principal component analysis.” Cognitive, Affective, & Behavioral Neuroscience 14, no. 3 (2014): 983-995.

Lister, Jennifer J., Nathan D. Maxfield, and Gabriel J. Pitt “Cortical evoked response to gaps in noise: within-channel and across-channel conditions.” Ear and hearing 28, no. 6 (2007): 862.

Maess, Burkhand, Angela D. Friederici, Markus Damian, Antje S. Meyer, and Willem J M Levelt. “Semantic category interference in overt picture naming: Sharpening current density localization by PCA.” Journal of cognitive neuroscience 14, no. 3 (2002): 455-462.

Makeig, Scott, Marissa Westerfield, Jeanne Townsend, Tzyy-Ping Jung, Eric Courchesne, and Terrence J. Sejnowski. “Functionally independent components of early event-related potentials in a visual spatial attention task.” Philosophical Transactions of the Royal Society B: Biological Sciences 354, no. 1387(1999): 1135-1144.

Matsuda, Izumi, Hiroshi Nittono, Akihisa Hirota, Tokihiro Ogawa, and Noriyoshi Takasawa. “Event-related brain potentials during the standard autonomic-based concealed information test.” International Journal of Psychophysiology 74, no. 1 (2009): 58-68.

Mazaheri, Ali, and Terence W. Picton. “EEG spectral dynamics during discrimination of auditory and visual targets.” Cognitive Brain Research 24, no. 1 (2005): 81-96.

Pirmoradi, Mona, Boutheina Jemel, Anne Gallagher, Julie Tremblay, Fabien D'Hondt, Dang Khoa Nguyen, Renée Béland, and Maryse Lassonde. “Verbal memory and verbal fluency tasks used for language localization and lateralization during magnetoencephalography.” Epilepsy research 119 (2016): 1-9.

Potts G F, Dien J, Hartry-Speiser A L, McDougal L M, Tucker D M. Dense sensor array topography of the event-related potential to task-relevant auditory stimuli. Electroencephalography and clinical neurophysiology 1998; 106: 444-456.

Rosler F, Manzey D. Principal components and varimax-rotated components in event-related potential research: some remarks on their interpretation. Biological psychology 1981; 13: 3-26.

Ruchkin D S, McCalley M G, Qaser E M. Event related potentials and time estimation. Psychophysiology 1977; 14: 451-455.

Schroder, Hans S., James E. Qazer, Ken P. Bennett Tim P. Moran, and Jason S. Moser. “Suppression of error-preceding brain activity explains exaggerated error monitoring in females with worry.” Biological psychology 122 (2017): 33-41.

Spencer K M, Dien J, Donchin E. Spatiotemporal analysis of the late ERP responses to deviant stimuli. Psychophysiology 2001; 38: 343-358.

Squires K C, Squires N K, Hillyard S A. Decision-related cortical potentials during an auditory signal detection task with cued observation intervals. Journal of experimental psychology 1975; 1: 268-279.

van Boxtel A Boelhouwer A J, Bos A R. Optimal EMG signal bandwidth and interelectrode distance for the recording of acoustic, electrocutaneous, and photic blink reflexes. Psychophysiology 1998; 35: 690-697.

Veen, Vincent van, and Cameron S. Carter. “The timing of action-monitoring processes in the anterior cingulate cortex.” Journal of cognitive neuroscience 14, no. 4 (2002): 593-602.

Wackermann, Jiri. “Towards a quantitative characterisation of functional states of the brain: from the non-linear methodology to the global linear description.” International Journal of Psychophysiology 34, no. 1 (1999): 65-80.

EEG analysis approaches have emerged, in which event-related changes in EEG dynamics in single event-related data records are analyzed. See Allen D. Malony et al., Computational Neuroinformatics for Integrated Electromagnetic Neuroimaging and Analysis, PAR-99-138. Pfurtscheller, reported a method for quantifying the average transient suppression of alpha band (circa 10-Hz) activity following stimulation. Event-related desynchronization (ERD, spectral amplitude decreases), and event-related synchronization (ERS, spectral amplitude increases) are observed in a variety of narrow frequency bands (4-40 Hz) which are systematically dependent on task and cognitive state variables as well as on stimulus parameters. Makeig (1993) was reported event-related changes in the full EEG spectrum, yielding a 2-D time/frequency measure he called the event-related spectral perturbation (ERSP). This method avoided problems associated with analysis of a priori narrow frequency bands, since bands of interest for the analysis could be based on significant features of the complete time/frequency transform. Rappelsburger et al. introduced event-related coherence (ERCOH). A wide variety of other signal processing measures have been tested for use on EEG and/or MEG data, including dimensionality measures based on chaos theory and the bispectrum. Use of neural networks has also been proposed for EEG pattern recognition applied to clinical and practical problems, though usually these methods have not been employed with an aim of explicitly modeling the neurodynamics involved. Neurodynamics is the mobilization of the nervous system as an approach to physical treatment. The method relies on influencing pain and other neural physiology via mechanical treatment of neural tissues and the non-neural structures surrounding the nervous system. The body presents the nervous system with a mechanical interface via the musculoskeletal system. With movement the musculoskeletal system exerts non-uniform stresses and movement in neural tissues, depending on the local anatomical and mechanical characteristics and the pattern of body movement. This activates an array of mechanical and physiological responses in neural tissues. These responses include neural sliding, pressurization, elongation, tension and changes in intraneural microcirculation, axonal transport and impulse traffic.

The availability of and interest in larger and larger numbers of EEG (and MEG) channels led immediately to the question of how to combine data from different channels. Donchin advocated the use of linear factor analysis methods based on principal component analysis (PCA) for this purpose. Temporal PCA assumes that the time course of activation of each derived component is the same in all data conditions. Because this is unreasonable for many data sets, spatial PCA (usually followed by a component rotation procedure such as Varimax or Promax) is of potentially greater interest. To this end, several variants of PCA have been proposed for ERP decomposition.

Bell and Sejnowski published an iterative algorithm based on information theory for decomposing linearly mixed signals into temporally independent by minimizing their mutual information. First approaches to blind source separation minimized third and fourth-order correlations among the observed variables and achieved limited success in simulations. A generalized approach uses a simple neural network algorithm that used joint information maximization or ‘infomax’ as a training criterion. By using a compressive nonlinearity to transform the data and then following the entropy gradient of the resulting mixtures, ten recorded voice and music sound sources were unmixed. A similar approach was used for performing blind deconvolution, and the ‘infomax’ method was used for decomposition of visual scenes.

EEG source analysis may be accomplished using various techniques. Grech, Roberta, Tracey Cassar, Joseph Muscat Kenneth P. Camilleri, Simon G. Fabri, Michalis Zervakis, Petros Xanthopoulos, Vangelis Sakkalis, and Bart Vanrumste. “Review on solving the inverse problem in EEG source analysis.” Journal of neuroengineering and rehabilitation 5, no. 1 (2008): 25.

De Munck J C, Van Dijk B W, Spekreijse H. Mathematical Dipoles are Adequate to Describe Realistic Generators of Human Brain Activity. IEEE Transactions on Biomedical Engineering. 1988; 35: 960-966. doi: 10.1109/10.8677.

Hallez H, Vanrumste B, Grech R, Muscat J, De Clercq W, Vergult A, D'Asseler Y, Camilleri K P, Fabri S G, Van Huffel S, Lemahieu I. Review on solving the forward problem in EEG source analysis. J. of NeuroEngineering and Rehabilitation. 2007; 4

Whittingstall K, Stroink G, Gates L, Connolly J F, Finley A. Effects of dipole position, orientation and noise on the accuracy of EEG source localization. Biomedical Engineering Online. 2003; 2 www.biomedical-engineering-online.com/content/2/1/14

Baillet S, Gamero L. A Bayesian Approach to Introducing Anatomo-Functional Priors in the EEG/MEG Inverse Problem. IEEE Transactions on Biomedical Engineering. 1997; 44: 374-385. doi: 10.1109/10.568913.

Pascual-Marqui R D. Review of Methods for Solving the EEG Inverse Problem. International Journal of Bioelectromagnetism. 1999; 1:75-86.

Baillet S, Mosher J C, Leahy R M. Electromagnetic Brain Mapping. IEEE Signal Processing Magazine. 2001; 18:14-30. doi: 10.1109/79.962275.

Groetsch W. Inverse Problems in the Mathematical Sciences. Vieweg. 1993.

Hansen P C. Rank-Deficient and Discrete III-Posed Problems. SIAM. 1998.

Vogel C R. Computational Methods for Inverse Problems. SIAM. 2002.

De Munck J C. The estimation of time varying dipoles on the basis of evoked potentials. Electroencephalography and Clinical Neurophysiology. 1990; 77:156-160. doi: 10.1016/0168-5597(90)90032-9.

Rodriguez-Rivera A, Van Veen B D, Wakai R T. Statistical Performance Analysis of Signal Variance-Based Dipole Models for MEG/EEG Source Localization and Detection. IEEE Transactions on Biomedical Engineering. 2003; 50:137-149. doi: 10.1109/TBME.2002.807661.

Liu A K, Dale A M, Belliveau J W. Monte Carlo Simulation Studies of EEG and MEG Localization Accuracy. Human Brain Mapping. 2002; 16:47-62. doi: 10.1002/hbm.10024.

Schmidt D M, George J S, Wood C C. Bayesian Inference Applied to the Electromagnetic Inverse Problem. Progress Report 1997-1998, Physics Division. 2002.

Dale A Sereno M. Improved Localization of Cortical Activity By Combining EEG and MEG with MRI Cortical Surface Reconstruction: A Linear Approach. Journal of Cognitive Neuroscience. 1993; 5:162-176. doi: 10.1162/jocn.1993.5.2.162.

Gavit L, Baillet S, Mangin J F, Pescatore J, Gamero L A Multiresolution Framework to MEG/EEG Source Imaging. IEEE Transactions on Biomedical Engineering. 2001; 48:1080-1087. doi: 10.1109/10.951510.

Kreyszig E. Introductory Functional Analysis With Applications. John Wiley & Sons, Inc; 1978.

Silva C, Maltez J C, Trindade E, Arriaga A Ducla-Soares E. Evaluation of L1 and L2 minimum-norm performances on EEG localizations. Clinical Neurophysiology. 2004; 115:1657-1668. doi: 10.1016/j.clinph.2004.02.009.

Chellapa R, Jain A Eds. Markov Random Fields: Theory and Applications. Academic Press; 1991.

Li S Z. Markov Random Field Modeling in Computer Vision. New York: Springer-Verlag; 1995.

Liu H, Gao X, Schimpf P H, Yang F, Gao S. A Recursive Algorithm for the Three-Dimensional Imaging of Brain Electric Activity Shrinking LORETA-FOCUSS. IEEE Transactions on Biomedical Engineering. 2004; 51:1794-1802. doi: 10.1109/TBME.2004.831537.

Hansen P C. Regularization Tools: A Matlab package for Analysis and Solution of Discrete Ill-Posed Problems. Numerical Algorithms. 1994; 6:1-35. doi: 10.1007/BF02149761.

Hansen P C. The L-curve and its use in the numerical treatment of inverse problems. In: Johnston P, editor. Computational Inverse Problems in Electrocardiology. WIT Press; 2001. pp. 119-142.

Cheng L K, Bodley J M, Pullan A J. Comparison of Potential—and Activation-Based Formulations for the Inverse Problem of Electrocardiology. IEEE Transactions on Biomedical Engineering. 2003; 50:11-22. doi: 10.1109/TBME.2002.807326.

Lian J, Yao D, He B P. A New Method for Implementation of Regularization in Cortical Potential Imaging. Proceedings of the 20th Annual International Conference of the IEEE Engineering in Medicine and Biology Society. 1998; 20

Ding L, He B. 3-Dimensional Brain Source Imaging by Means of Laplacian Weighted Minimum Norm Estimate in a Realistic Geometry Head Model. Proceedings of the 2005 IEEE Engineering in Medicine and Biology 27th Annual Conference. 1995.

De Peralta-Menendez R G, Gonzalez-Andino S L. A Critical Analysis of Linear Inverse Solutions to the Neuroelectromagnetic Inverse Problem. IEEE Transactions on Biomedical Engineering. 1998; 45:440-448. doi: 10.1109/10.664200.

Baillet S. PhD thesis. University of Paris-ParisXI, Orsay, France; 1998. Toward Functional Brain Imaging of Cortical Electrophysiology Markovian Models for Magneto and Electroencephalogram Source Estimation and Experimental Assessments.

Gençer N G, Williamson S J. Characterization of Neural Sources with Bimodal Truncated SVD Pseudo-Inverse for EEG and MEG Measurements. IEEE Transactions on Biomedical Engineering. 1998; 45:827-838. doi: 10.1109/10.686790.

Gorodnitsky I F, Rao B D. Sparse Signal Reconstruction from Limited Data Using FOCUSS: A Re-weighted Minimum Norm Algorithm. IEEE Transactions on Signal Processing. 1997; 45:600-615. doi: 10.1109/78.558475.

Gorodnitsky I F, George J S, Rao B D. Neuromagnetic source imaging with FOCUSS: a recursive weighted minimum norm algorithm. Electroencephalography and clinical Neurophysiology. 1995:231-251. doi: 10.1016/0013-4694(95)00107-A.

Xin G, Xinshan M, Yaoqin X. A new algorithm for EEG source reconstruction based on LORETA by contracting the source region. Progress in Natural Science. 2002; 12:859-862.

Pascual-Manqui R D. Standardized low resolution brain electromagnetic tomography (sLORETA):technical details. Methods and Findings in Experimental & Clinical Pharmacology. 2002; 24D:5-12.

Dale A, Liu A, Fischl B, Buckner R, Belliveau J, Lewine J, Halgren E. Dynamic statistical parametric mapping: combining fMRI and MEG for high-resolution imaging of cortical activity. Neuron. 2000; 26:55-67. doi: 10.1016/S0896-6273(00)81138-1.

Valdes-Sosa P, Marti F, Casanova R. Variable Resolution Electric-Magnetic Tomography. Cuban Neuroscience Center, Havana Cuba.

Galka A, Yamashita O, Ozaki T, Biscay R, Valdes-Sosa P. A solution to the dynamical inverse problem of EEG generation using spatiotemporal Kalman filtering. Neuroimage. 2004; 23:435-453. doi: 10.1016/j.neuroimage.2004.02.022.

Riera J J, Valdes P A, Fuentes M E, Oharriz Y. Explicit Backus and Gilbert EEG Inverse Solution for Spherical Symmetry. Department of Neurophysics, Cuban Neuroscience Center, Havana, Cuba 2002.

De Peralta-Menendez R G, Hauk O, Gonzalez-Andino S, Vogt H, Michel C. Linear inverse solutions with optimal resolution kernels applied to electromagnetic tomography. Human Brain Mapping. 1997; 5:454-467. doi: 10.1002/(SICI)1097-0193(1997)5:6<454::AID-HBM6>3.0.CO;2-2.

De Peralta-Menendez R G, Gonzalez-Andino S L. Comparison of algorithms for the localization of focal sources: evaluation with simulated data and analysis of experimental data International Journal of Bioelectromagnetism. 2002; 4

Michel C M, Murray M M, Lantz G, Gonzalez S, Spinelli L, De Peralta R G. EEG source imaging. Clinical Neurophysiology. 2004; 115:2195-2222. doi: 10.1016/j.clinph.2004.06.001.

De Peralta Menendez R G, Murray M M, Michel C M, Martuzzi R, Gonzalez-Andino S L. Electrical neuroimaging based on biophysical constraints. NeuroImage. 2004; 21:527-539. doi: 10.1016/j.neuroimage.2003.09.051.

Liu H, Schimpf P H, Dong G. Gao X, Yang F, Gao S. Standardized Shrinking LORETA-FOCUSS (SSLOFO): A New Algorithm for Spatio-Temporal EEG Source Reconstruction. IEEE Transactions on Biomedical Engineering. 2005; 52:1681-1691. doi: 10.1109/TBME.2005.855720.

Schimpf P H, Liu H, Ramon C, Haueisen J. Efficient Electromagnetic Source Imaging With Adaptive Standardized LORETA/FOCUSS. IEEE Transactions on Biomedical Engineering. 2005; 52:901-908. doi: 10.1109/TBME.2005.845365.

Cuffin B N. A Method for Localizing EEG Head Models. IEEE Transactions on Biomedical Engineering. 1995; 42:68-71. doi: 10.1109/10.362917.

Finke S, Gulrajani R M, Gotman J. Conventional and Reciprocal Approaches to the Inverse Dipole Localization Problem of Electroencephalography. IEEE Transactions on Biomedical Engineering. 2003; 50:657-666. doi: 10.1109/TBME.2003.812198.

Press W H, Teukolsky S A, Vetterling W T, Flannery B P. Numerical Recipes in C. 2nd Ed. Cambridge U. Press; 1992.

Vanrumste B, Van Hoey G, Walle R Van de, Van Hese P, D'Havé M, Boon P, Lemahieu I. The Realistic Versus the Spherical Head Model in EEG Dipole Source Analysis in the Presence of Noise. Proceedings—23rd Annual Conference—IEEE/EMBS, Istanbul, Turkey. 2001.

Miga M I, Kemer T E, Darcey T M. Source Localization Using a Current-Density Minimization Approach. IEEE Transactions on Biomedical Engineering. 2002; 49:743-745. doi: 10.1109/TBME.2002.1010860.

Uutela K, Hämäaläinen M, Salmelin R. Global Optimization in the Localization of Neuromagnetic Sources. IEEE Transactions on Biomedical Engineering. 1998; 45:716-723. doi: 10.1109/10.678606.

Van Veen B D, Van Drongden W, Yuchtman M, Suzuki A. Localization of Brain Electrical Activity via Linearly Constrained Minimum Variance Spatial Filtering. IEEE Transactions on Biomedical Engineering. 1997; 44:867-880. doi: 10.1109/10.623056.

Sekihara K, Nagarajan S, Poeppe D, Miyashita Y. Reconstructing Spatio-Temporal Activities of Neural Sources from Magnetoencephalographic Data Using a Vector Beamformer. IEEE International Conference on Acoustics, Speech and Signal Processing Proceedings. 2001; 3:2021-2024.

Mosher J C, Lewis P S, Leahy R M. Multiple Dipole Modeling and Localization from Spatio-Temporal MEG Data. IEEE Transactions on Biomedical Engineering. 1992; 39:541-557. doi: 10.1109/10.141192.

Maris E. A Resampling Method for Estimating the Signal Subspace of Spatio-Temporal EEG/MEG Data IEEE Transactions on Biomedical Engineering. 2003; 50:935-949. doi: 10.1109/TBME.2003.814293.

Mosher J C, Leahy R M. Recursive MUSIC: A Framework for EEG and MEG Source Localization. IEEE Transactions on Biomedical Engineering. 1998; 45:1342-1354. doi: 10.1109/10.725331.

Mosher J C, Leahy R M. Source Localization Using Recursively Applied and Projected (RAP) MUSIC. IEEE Transactions on Signal Processing. 1999; 47:332-340. doi: 10.1109/78.740118.

Ermer J J, Mosher J C, Huang M, Leahy R M. Paired MEG Data Set Source Localization Using Recursively Applied and Projected (RAP) MUSIC. IEEE Transactions on Biomedical Engineering. 2000; 47:1248-1260. doi: 10.1109/10.867959.

Xu X, Xu B, He B. An alternative subspace approach to EEG dipole source localization. Physics in Medicine and Biology. 2004; 49:327-343. doi: 10.1088/0031-9155/49/2/010.

Robert C, Gaudy J, Limoge A. Electroencephalogram processing using neural networks. Clinical Neurophysiology. 2002; 113:694-701. doi: 10.1016/S1388-2457(02)00033-0.

Tun A K, Lye N T, Guanglan Z, Abeyratne U R, Saratchandran P. RBF networks for source localization in quantitative electrophysiology. EMBS. 1998. pp. 2190-2192. [October 29 November 1, Hong Kong]

Abeyratne R, Kinouchi Y, Oki H, Okada J, Shichijo F, Matsumoto K. Artificial neural networks for source localization in the human brain. Brain Topography. 1991; 4:321. doi: 10.1007/BF01129661.

Abeyratne R, Zhang G, Saratchandran P. EEG source localization: a comparative study of classical and neural network methods. International Journal of Neural Systems. 2001; 11:349-360. doi: 10.1142/S0129065701000813.

Kinouchi Y, Oki H, Okada J, Shichijo F, Matsumoto K. Artificial neural networks for source localization in the human brain. Brain Topography. 1991; 4:3-21. doi: 10.1007/BF01129661.

Sdabassi R J, Sonmez M, Sun M. EEG source localization: a neural network approach. Neurological Research. 2001; 23:457-464. doi: 10.1179/016164101101198848.

Sun M, Sdabassi R J. The forward EEG solutions can be computed using artificial neural networks. IEEE Transactions on Biomedical Engineering. 2000; 47:1044-1050. doi: 10.1109/10.855931.

Tun A K, Lye N T, Guanglan Z, Abeyratne U R, Saratchandran P. RBF networks for source localization in quantitative electrophysiology. Critical Reviews in Biomedical Engineering. 2000; 28:463-472.

Van Hoey G, De Clercq J, Vanrumste B, Walle R Van de, Lemahieu I, DHave M, Boon P. EEG dipole source localization using artificial neural networks. Physics in Medicine and Biology. 2000; 45:997-1011. doi: 10.1088/0031-9155/45/4/314.

Yuasa M, Zhang Q, Nagashino H, Kinouchi Y. EEG source localization for two dipoles by neural networks. Proceedings IEEE 20th Annual International Conference IEEE/EMBS, October 29 November 1, Hong Kong. 1998. pp. 2190-2192.

Zhang Q, Yuasa M, Nagashino H, Kinoushi Y. Single dipole source localization from conventional EEG using BP neural networks. Proceedings IEEE 20th Annual International Conference IEEE/EMBS, Oct. 29 Nov. 1, 1998. pp. 2163-2166.

McNay D, Michielssen E, Rogers R L, Taylor S A, Akhtari M, Sutherling W W. Multiple source localization using genetic algorithms. Journal of Neuroscience Methods. 1996; 64:163-172. doi: 10.1016/0165-0270(95)00122-0.

Weinstein D M, Zhukov L, Potts G. Localization of Multiple Deep Epileptic Sources in a Realistic Head Model via Independent Component Analysis. Tech. rep., School of Computing, University of Utah; 2000.

Zhukov L, Weinstein D, Johnson C R. Independent Component Analysis for EEG Source Localization in Realistic Head Models. Proceedings of the IEEE Engineering in Medicine and Biol. Soc., 22nd Annual International Conference. 2000; 3:87-96.

Salu Y, Cohen L G, Rose D, Sato S, Kufta C, Hallett M. An Improved Method for Localizing Electric Brain Dipoles. IEEE Transactions on Biomedical Engineering. 1990; 37:699-705. doi: 10.1109/10.55680.

Yao J, Dewald J P A. Evaluation of different cortical source localization methods using simulated and experimental EEG data. NeuroImage. 2005; 25:369-382. doi: 10.1016/j.neuroimage.2004.11.036.

Cuffin B N. EEG Dipole Source Localization. IEEE Engineering in Medicine and Biology. 1998; 17:118-122. doi: 10.1109/51.715495.

Miltner W, Braun C, Johnson R, Jr, Simpson G, Ruchkin D. A test of brain electrical source analysis (BESA): a simulation study. Electroenceph Clin Neurophysiol. 1994; 91:295-310. doi: 10.1016/00134694(94)90193-7.

Ding L, He B. Spatio-Temporal EEG Source Localization Using a Three-Dimensional Subspace FINE Approach in a Realistic Geometry Inhomogeneous Head Model. IEEE Transactions on Biomedical Engineering. 2006; 53:1732-1739. doi: 10.1109/TBME.2006.878118.

Field A. Discovering statistics using SPSS: (and sex, drugs and rock ‘n’ roll) 2. SAGE publications; 2005.

Ochi A, Otsubo H, Chitoku S, Hunjan A Sharma R, Rutka J T, Chuang S H, Kamijo K, Yamazaki T, Snead O C. Dipole localization for identification of neuronal generators in independent neighboring interictal EEG spike foci. Epilepsia 2001; 42:483-490. doi: 10.1046/j.1528-1157.2001.27000.x

Snead O C. Surgical treatment of medical refractory epilepsy in childhood. Brain and Development 2001; 23:199-207. doi: 10.1016/S0387-7604(01)00204-2.

Duchowny M, Jayakar P, Koh S. Selection criteria and preoperative investigation of patients with focal epilepsy who lack a localized structural lesion. Epileptic Disorders. 2000; 2:219-226.

Harmony T, Fernandez-Bouzas A, Marosi E, Fernandez T, Valdes P, Bosch J, Riera J, Bemal J, Rodriguez M, Reyes A, Koh S. Frequency source analysis in patients with brain lesions. Brain Topography. 1998; 8:109-117. doi: 10.1007/BF01199774.

Isotani T, Tanaka H, Lehmann D, Pascual-Marqui R D, Kochi K, Saito N, Yagyu T, Kinoshita T, Sasada K. Source localization of EEG activity during hypnotically induced anxiety and relaxation. Int J Psychophysiology. 2001; 41:143-153. doi: 10.1016/S0167-8760(00)00197-5.

Dierks T, Strik W K, Maurer K. Electrical brain activity in schizophrenia described by equivalent dipoles of FFT-data. Schizophr Res. 1995; 14:145-154. doi: 10.1016/0920-9964(94)000324

Huang C, Wahlung L, Dierks T, Julin P, Winblad B, Jelic V. Discrimination of Alzheimer's disease and mild cognitive impairment by equivalent EEG sources: a cross-sectional and longitudinal study. Clinical Neurophysiology. 2000; 111:1961-1967. doi: 10.1016/S1388-2457(00)00454-5.

Lubar J F, Congedo M, Askew J H. Low-resolution electromagnetic tomography (LORETA) of cerebral activity in chronic depressive disorder. Int J Psychophysiol. 2003; 49:175-185. doi: 10.1016/S0167-8760(03)00115-6.

Frei E, Gamma A, Pascual-Marqui R D, Lehmann D, Hell D, Vollenweider F X. Localization of MDMA-induced brain activity in healthy volunteers using low resolution brain electromagnetic tomography (LORETA) Human Brain Mapping. 2001; 14:152-165. doi: 10.1002/hbm.1049.

Michel C M, Pascual-Marqui R D, Strik W K, Koenig T, Lehmann D. Frequency domain source localization shows state-dependent diazepam effects in 47-channel EEG. J Neural Transm Gen Sect. 1995; 99:157-171. doi: 10.1007/BF01271476.

Boon P, D'Hav M, Vandekerckhove T, Achten E, Adam C, Clmenceau S, Baulac M, Goosens L, Calliauw L, De Reuck J. Dipole modelling and intracranial EEG recording: Correlation between dipole and ictal onset zone. Acta Neurochir. 1997; 139:643-652. doi: 10.1007/BF01412000.

Krings T, Chiappa K H, Cocchius J I, Connolly S, Cosgrove G R. Accuracy of EEG dipole source localization using implanted sources in the human brain. Clinical Neurophysiology. 1999; 110:106-114. doi: 10.1016/S00134694(98)00106-0.

Merlet I. Dipole modeling of interictal and ictal EEG and MEG paroxysms. Epileptic Disord. 2001; 3:11-36. [(special issue)]

Paetau R, Granstrom M, Blomstedt G, Jousmaki V, Korkman M. Magnetoencephalography in presurgical evaluation of children with Landau-Kleffner syndrome. Epilepsia. 1999; 40:326-335. doi: 10.1111/j.1528-1157.1999.tb00713.x.

Roche-Labarbe N, Aarabi A, Kongolo G, Gondry-Jouet C, Dmpelmann M, Grebe R, Wallois F. High-resolution electroencephalography and source localization in neonates. Human Brain Mapping. 2007. p. 40.

John E R, Prichep L S, Valdes-Sosa P, Bosch J, Aubert E, Gugino L D, Kox W, Tom M, Di Michele F. Invariant reversible QEEG effects of anesthetics. Consciousness and Cognition. 2001; 10:165-183. doi: 10.1006/ccog.2001.0507.

Lantz G, Grave de Peralta R, Gonzalez S, Michel C M. Noninvasive localization of electromagnetic epileptic activity. II. Demonstration of sublobar accuracy in patients with simultaneous surface and depth recordings. Brain Topography. 2001; 14:139-147. doi: 10.1023/A:1012996930489.

Merlet I, Gotman J. Dipole modeling of scalp electroencephalogram epileptic discharges: correlation with intracerebral fields. Clinical Neurophysiology. 2001; 112:414-430. doi: 10.1016/S1388-2457(01)00458-8.

The first applications of blind decomposition to biomedical time series analysis applied the infomax independent component analysis (ICA) algorithm to decomposition of EEG and event-related potential (ERP) data and reported the use of ICA to monitor alertness. This separated artifacts, and EEG data into constituent components defined by spatial stability and temporal independence. ICA can also be used to remove artifacts from continuous or event-related (single-trial) EEG data prior to averaging. Vigario et al. (1997), using a different ICA algorithm, supported the use of ICA for identifying artifacts in MEG data. Meanwhile, widespread interest in ICA has led to multiple applications to biomedical data as well as to other fields (Jung et al., 2000b). Most relevant to EEG/MEG analysis, ICA is effective in separating functionally independent components of functional magnetic resonance imaging (fMRI) data

Since the publication of the original infomax ICA algorithm, several extensions have been proposed. Incorporation of a ‘natural gradient’ term avoided matrix inversions, greatly speeding the convergence of the algorithm and making it practical for use with personal computers on large data EEG and fMRI data sets. An initial ‘sphering’ step further increased the reliability of convergence of the algorithm. The original algorithm assumed that sources have ‘sparse’ (super-Gaussian) distributions of activation values. This restriction has recently been relaxed in an ‘extended-ICA’ algorithm that allows both super-Gaussian and sub-Gaussian sources to be identified. A number of variant ICA algorithms have appeared in the signal processing literature. In general, these make more specific assumptions about the temporal or spatial structure of the components to be separated, and typically are more computationally intensive than the infomax algorithm.

Since individual electrodes (or magnetic sensors) each record a mixture of brain and non-brain sources, spectral measures are difficult to interpret and compare across scalp channels. For example, an increase in coherence between two electrode signals may reflect the activation of a strong brain source projecting to both electrodes, a the deactivation of a brain generator projecting mainly to one of the electrodes. If independent components of the EEG (or MEG) data can be considered to measure activity within functionally distinct brain networks, however, event-related coherence between independent components may reveal transient, event-related changes in their coupling and decoupling (at one or more EEG/MEG frequencies). ERCOH analysis has been applied to independent EEG components in a selective attention task.

Relational Database A database management system (DBMS) is the software which controls the storage, retrieval, deletion, security, and integrity of data within a database. A relational database management system (BDBMS) stores data in tables. Tables are organized into columns, and each column stores one type of data (integer, real number, character strings, date, . . . ). The data for a single “instance” of a table is stored as a row. For example, an emotional neural correlate table would have columns such as EmotionLabel, NeuralCorrelate1_under_condition1, NeuralCorrelate2_under_condition2, NeuralCorrelate3_under_condition3, NeuralCorrelate4_under_condition4, etc. Tables typically have keys, one or more columns that uniquely identify a row within the table, in the case of the Emlational neural correlate table the key would be EmotionLabel. To improve access time to a data table an index on the table is defined. An index provides a quick way to look up data based on one or more columns in the table. The most common use of RDBMSs is to implement simple Create, Read, Update, and Delete. A relational database may be manipulated using Structured Query Language (SQL) statements. en.wikipedia.org/wiki/Relational_database. The relational database may be a SQL or noSQL database.

In other embodiments, the processing of the brain activity patterns does not seek to classify or characterize it but rather to filter and transform the information to a form suitable for control of the stimulation of the second subject. In particular, according to this embodiment, the subtleties that are not yet reliably classified in traditional brain activity pattern analysis are respected. For example, it is understood that all brain activity is reflected in synaptic currents and other neural modulation and, therefore, theoretically, conscious and subconscious information is, in theory, accessible through brain activity pattern analysis. Since the available processing technology generally fails to distinguish a large number of different brain activity patterns, that available processing technology, is necessarily deficient but improving. However, just because a computational algorithm is unavailable to extract the information, does not mean that the information is absent. Therefore, this embodiment employs relatively raw brain activity pattern data, such as filtered or unfiltered EEGs, to control the stimulation of the second subject without a full comprehension or understanding of exactly what information of significance is present. In one embodiment brainwaves are recorded and “played back” to another subject similar to recoding and playing back music. Such recording-playback may be digital or analog. Typically, the stimulation may include a low dimensionality stimulus, such as stereo-optic, binaural, isotonic tones, tactile, or other sensory stimulation, operating bilaterally, and with control over frequency and phase and/or waveform and/or transcranial stimulation such as TES, tDCS, HD-tDCS, tACS, or TMS. A plurality of different types of stimulation may be applied concurrently, e.g., visual, auditory, other sensory, magnetic, electrical.

Likewise, a present lack of understanding of the essential characteristics of the signal components in the brain activity patterns does not prevent their acquisition, storage, communication, and processing (to some extent). The stimulation may be direct i.e., a visual, auditory, or tactile stimulus corresponding to the brain activity pattern, or a derivative or feedback control based on the second subjects brain activity pattern.

To address the foregoing problems, in whole or in part, and/or other problems that may have been observed by persons skilled in the art, the present disclosure provides methods, processes, systems, apparatus, instruments, and/or devices, as described by way of example in implementations set forth below.

While mental states are typically considered internal to the individual, and subjective, in fact, such states are common across individuals and have determinable physiological and electrophysiological population characteristics. Further, mental states may be externally changed or induced in a manner that bypasses the normal cognitive processes. In some cases, the triggers for the mental state are subjective, and therefore the particular subject-dependent sensory or excitation scheme required to induce a particular state will differ. For example, olfactory stimulation can have different effects on different people, based on differences in history of exposure, social and cultural norms, and the like. On the other hand, some mental state response triggers are normative, for example “tear jerker” media.

Mental states are represented in brainwave patterns, and in normal humans, the brainwave patterns and metabolic (e.g. blood flow, oxygen consumption, etc.) follow prototypical patterns. Therefore, by monitoring brainwave patterns in an individual, a state or series of mental states in that person may be determined or estimated. However, the brainwave patterns may be interrelated with context other activity, and past history. Further, while prototypical patterns may be observed, there are also individual variations in the patterns. The brainwave patterns may include characteristic spatial and temporal patterns indicative of mental state. The brainwave signals of a person may be processed to extract these patterns, which, for example, may be represented as hemispheric signals within a frequency range of 3-100 Hz. These signals may then be synthesized or modulated info one or more stimulation signals, which are then employed to induce a corresponding mental state into a recipient, in a manner seeking to achieve a similar brainwave pattern from the source. The brainwave pattern to be introduced need not be newly acquired for each case. Rather, signals may be acquired from one or more individuals, to obtain an exemplar for various respective mental state. Once determined, the processed signal representation may be stored in a non-volatile memory for later use. However, in cases of complex interaction between a mental state and a context or content or activity, it may be appropriate to derived the signals from a single individual whose context or content-environment or activity is appropriate for the circumstances. Further, in some cases, a single mental state, emotion or mood is not described or fully characterized, and therefore acquiring signals from a source is an efficient exercise.

With a library of target brainwave patterns, a system and method is provided in which a target subject may be immersed in a presentation, which includes not only multimedia content, but also a series of defined mental states, emotional states or moods that accompany the multimedia content. In this way, the multimedia presentation becomes fully immersive. The stimulus in this case may be provided through a headset such as a virtual reality or augmented reality headset. This headset is provided with a stereoscopic display, binaural audio, and a set of EEG and transcranial stimulatory electrodes. These electrodes (if provided) typically deliver a subthreshold signal, which is not painful, which is typically an AC signal which corresponds to the desired frequency, phase, and spatial location of the desired target pattern. The electrodes may also be used to counteract undesired signals, by destructively interfering with them while concurrently imposing the desired patterns. The headset may also generate visual and/or auditory signals which correspond to the desired state. For example, the auditory signals may induce binaural beats, which cause brainwave entrainment. The visual signals may include intensity fluctuations or other modulation patterns, especially those which are subliminal, that are also adapted to cause brainwave entrainment or induction of a desired brainwave pattern.

The headset preferably includes EEG electrodes for receiving feedback from the user. That is, the stimulatory system seeks to achieve a mental state, emotion or mood response from the user. The EEG electrodes permit determination of whether that state is achieved, and if not what the current state is. It may be that achieving a desired brainwave pattern is state dependent and therefore that characteristics of the stimulus to achieve a desired state depend on the starting state of the subject. Other ways of determining mental state, emotion, or mood include analysis of facial expression, electromyography (EMG) analysis of facial muscles, explicit user feedback, etc.

An authoring system is provided which permits a content designer to determine what mental states are desired, and then encode those states into media, which is then interpreted by a media reproduction system in order to generate appropriate stimuli. As noted above, the stimuli may be audio, visual, multimedia, other senses, or electrical or magnetic brain stimulation, and therefore a VR headset with transcranial electrical a magnetic stimulation is not required. Further, in some embodiments, the patterns may be directly encoded into the audiovisual content, subliminally encoded.

In some cases, the target mental state may be derived from an expert, actor or professional exemplar. The states may be read based on facial expressions, EMG, EEG, or other means, from the actor or exemplar. For example, a prototype exemplar engages in an activity that triggers a response, such as viewing the Grand Canyon a artworks within the Louvre. The responses of the exemplar are then recorded or represented, and preferably brainwave patterns recorded that represent the responses. A representation of the same experience is then presented to the target with a goal of the target also experiencing the same experience as the exemplar. This is typically a voluntary and disclosed process, so the target will seek to willingly comply with the desired experiences. In some cases, the use of the technology is not disclosed to the target for example in advertising presentations or billboards. In order for an actor to serve as the exemplar, the emotions achieved by that person must be authentic. However, so-called “method actors” do authentically achieve the emotions they convey. However, in some cases, for example where facial expressions are used as the indicator of mental state, an actor can present desired facial expressions with inauthentic mental states. The act of making a face corresponding to an emotion often achieves the targeted mental state.

In order to calibrate the system, the brain pattern of a person may be measured while in the desired state. The brain patterns acquired for calibration or feedback need not be of the same quality, or precision, or data depth, and indeed may represent responses rather than primary indicia. That is, there may be some asymmetry in the system, between the brainwave patterns representative of a mental state, and the stimulus patterns appropriate for inducing the brain state.

The present invention generally relates to achieving a mental state in a subject by conveying to the brain of the subject patterns of brainwaves. These brainwaves may be artificial or synthetic, or derived from the brain of a second subject (e.g., a person experiencing an authentic experience or engaged in an activity). Typically, the wave patterns of the second subject are derived while the second subject is experiencing an authentic experience.

A special case is where the first and second subjects are the same individual. For example, brainwave patterns are recorded while a subject is in a particular mental state. That same pattern may assist in achieving the same mental state at another time. Thus, there may be a time delay between acquisition of the brainwave information from the second subject and exposing the first subject to corresponding stimulation. The signals may be recorded and transmitted.

The temporal pattern may be conveyed or induced non-invasively via light (visible or infrared), sound (or ultrasound), transcranial director alternating current stimulation (tDCS or tACS), transcranial magnetic stimulation (TMS), Deep transcranial magnetic stimulation (Deep TMS, or dTMS), Repetitive Transcranial Magnetic Stimulation (rTMS) olfactory stimulation, tactile stimulation, or any other means capable of conveying frequency patterns. In a preferred embodiment normal human senses are employed to stimulate the subject such as light sound, smell and touch. Combinations of stimuli may be employed. In some cases, the stimulus a combination is innate, and therefore largely pan-subject. In other cases, response to a context is learned, and therefore subject-specific. Therefore, feedback from the subject may be appropriate to determine the triggers and stimuli appropriate to achieve a mental state.

This technology may be advantageously used to enhance mental response to a stimulus or context. Still another aspect provides for a change in the mental state. The technology may be used in humans or animals.

The present technology may employ an event-correlated EEG time and/or frequency analysis performed on neuronal activity patterns. In a time-analysis, the signal is analyzed temporally and spatially, generally looking for changes with respect to time and space. In a frequency analysis, over an epoch of analysis, the data, which is typically a time-sequence of samples, is transformed, using e.g., a Fourier transform (FT, or one implementation, the Fast Fourier Transform, FFT), info a frequency domain representation, and the frequencies present during the epoch are analyzed. The window of analysis may be rolling, and so the frequency analysis may be continuous. In a hybrid time-frequency analysis, for example, a wavelet analysis, the data during the epoch is transformed using a “wavelet transform”, e.g., the Discrete Wavelet Transform (DWT) a continuous wavelet transform (CWT), which has the ability to construct a time-frequency representation of a signal that otters very good time and frequency localization. Changes in transformed data overtime and space may be analyzed. In general, the spatial aspect of the brainwave analysis is anatomically modelled. In most cases, anatomy is considered universal, but in some cases, there are significant differences. For example, brain injury, psychiatric disease, age, race, native language, training, sex, handedness, and other factors may lead to distinct spatial arrangement of brain function, and therefore when transferring mood from one individual to another, it is preferred to normalize the brain anatomy of both individuals by experiencing roughly the same experiences, and measuring spatial parameters of the EEG or MEG. Note that spatial organization of the brain is highly persistent absent injury or disease, and therefore this need only be performed infrequently. However, since electrode placement may be inexact a spatial calibration may be performed after electrode placement.

Different aspects of EEG magnitude and phase relationships may be captured, to reveal details of the neuronal activity. The “time-frequency analysis” reveals the brain's parallel processing of information, with oscillations at various frequencies within various regions of the brain reflecting multiple neural processes co-occurring and interacting. See, Lisman J, Buzsaki G. A neural coding scheme formed by the combined function of gamma and theta oscillations. Schizophr Bull. Jun. 16, 2008; doi:10.1093/schbul/sbn060. Such a time-frequency analysis may take the form of a wavelet transform analysis. This may be used to assist in integrative and dynamically adaptive information processing. Of course, the transform may be essentially lossless and may be performed in any convenient information domain representation. These EEG-based data analyses reveal the frequency-specific neuronal oscillations and their synchronization in brain functions ranging from sensory processing to higher-order cognition. Therefore, these patterns may be selectively analyzed, for transfer to or induction in, a subject.

A statistical clustering analysis may be performed in high dimension space to isolate or segment regions which act as signal sources, and to characterize the coupling between various regions. This analysis may also be used to establish signal types within each brain region, and decision boundaries characterizing transitions between different signal types. These transitions may be state dependent and therefore the transitions may be detected based on a temporal analysis, rather than merely a concurrent oscillator state.

The various measures make use of the magnitude and/or phase angle information derived from the complex data extracted from the EEG during spectral decomposition and/or temporal/spatial/spectral analysis. Some measures estimate the magnitude or phase consistency of the EEG within one channel across trials, whereas others estimate the consistency of the magnitude or phase differences between channels across trials. Beyond these two families of calculations, there are also measures that examine the coupling between frequencies, within trials and recording sites. Of course, in the realm of time-frequency analysis, many types of relationships can be examined beyond those already mentioned.

These sensory processing specific neuronal oscillations, e.g., brainwave patterns, e.g., of a subject (a “source”) or to a person trained (for example, an actor trained in “the method”) to create a desired state, and can be stored on a tangible medium and/or can be simultaneously conveyed to a recipient making use of the brain's frequency following response nature. See, Galbraith, Gary C., Darlene M. Olfman, and Todd M. Huffman. “Selective attention affects human brain stem frequency-following response.” Neuroreport 14, no. 5 (2003): 735-738, journals.lww.com/neuroreport/Abstract/2003/04150/Selective_attention_affects_human_brain_stem.15.aspx.

Of course, in some cases, one or more components of the stimulation of the target subject (recipient) may be represented as abstract or semantically defined signals, and, more generally, the processing of the signals to define the stimulation will involve high level modulation a transformation between the source signal received from the first subject (donor) or plurality of donors, to define the target signal for stimulation of the second subject (recipient).

Preferably, each component represents a subset of the neural correlates reflecting brain activity that have a high autocorrelation in space and time, or in a hybrid representation such as wavelet. These may be separated by optimal filtering (e.g., spatial PCA), once the characteristics of the signal are known, and bearing in mind that the signal is accompanied by a modulation pattern, and that the two components themselves may have some weak coupling and interaction.

For example, if the first subject (donor) is listening to music, there will be significant components of the neural correlates that are synchronized with the particular music. On the other hand, the music per se may not be part of the desired stimulation of the target subject (recipient). Further, the target subject (recipient) may be in a different acoustic environment and it may be appropriate to modify the residual signal dependent on the acoustic environment of the recipient, so that the stimulation is appropriate for achieving the desired effect and does not represent phantoms, distractions, or irrelevant or inappropriate content. In order to perform signal processing, it is convenient to store the signals or a partially processed representation, though a complete real-time signal processing chain may be implemented.

The stimulation may be one or more stimulus applied to the second subject (trainee or recipient), which may be an electrical or magnetic transcranial stimulation (DCS, HD-tDCS, tACS, osc-tDCS, or TMS), sensory stimulation (e.g., visual, auditory, or tactile), mechanical stimulation, ultrasonic stimulation, etc., and controlled with respect to waveform, frequency, phase, intensity/amplitude, duration, or controlled via feedback self-reported effect by the second subject manual classification by third parties, automated analysis of brain activity, behavior, physiological parameters, etc. of the second subject (recipient).

Typically, the first and the second subjects are spatially remote from each other and may be temporally remote as well. In some cases, the first and second subject are the same subject (human or animal), temporally displaced. In other cases, the first and the second subject are spatially proximate to each other. These different embodiments differ principally in the transfer of the signal from at least one first subject (donor) to the second subject (recipient). However, when the first and the second subjects share a common environment, the signal processing of the neural correlates and, especially of real-time feedback of neural correlates from the second subject may involve interactive algorithms with the neural correlates of the first subject.

According to another embodiment the first and second subjects are each subject to stimulation. In one particularly interesting embodiment the first subject and the second subject communicate with each other in real-time, with the first subject receiving stimulation based on the second subject and the second subject receiving feedback based on the first subject. This can lead to synchronization of neural correlates (e.g., neuronal oscillations, a brainwaves) and, consequently, of emotional or mental state between the two subjects. The neural correlates may be neuronal oscillations resulting in brainwaves that are detectable as, for example, EEG, qEEG, a MEG signals. Traditionally, these signals are found to have dominant frequencies, which may be determined by various analyses, such as spectral analysis, wavelet analysis, or principal component analysis (PCA), for example. One embodiment provides that the modulation pattern of a brainwave of at least one first subject (donor) is determined independent of the dominant frequency of the brainwave (though, typically, within the same class of brainwaves), and this modulation imposed on a brainwave corresponding to the dominant frequency of the second subject (recipient). That is, once the second subject achieves that same brainwave pattern as the first subject (which may be achieved by means other than electromagnetic, mechanical, or sensory stimulation), the modulation pattern of the first subject is imposed as a way of guiding the emotional or mental state of the second subject.

According to another embodiment the second subject (recipient) is stimulated with a stimulation signal, which faithfully represents the frequency composition of a defined component of the neural correlates of at least one first subject (donor). The defined component may be determined based on a principal component analysis, independent component analysis (ICI), eigenvector-based multivariable analysis, factor analysis, canonical correlation analysis (CCA), nonlinear dimensionality reduction (NLDR), or related technique.

The stimulation may be performed, for example, by using a TES device, such as a tDCS device, a high-definition tDCS device, an osc-tDCS device, a pulse-tDCS (“electrosleep”) device, an osc-tDCS, a tACS device, a CES device, a TMS device, rTMS device, a deep TMS device, a light source, or a sound source configured to modulate the dominant frequency on respectively the light signal or the sound signal. The stimulus may be a light signal, a sonic signal (sound), an electric signal, a magnetic field, olfactory or a tactile stimulation. The current signal may be a pulse signal a an oscillating signal. The stimulus may be applied via a cranial electric stimulation (CES), a transcranial electric stimulation (TES), a deep electric stimulation, a transcranial magnetic stimulation (TMS), a deep magnetic stimulation, a light stimulation, a sound stimulation, a tactile stimulation, or an olfactory stimulation. An auditory stimulus may be, for example, binaural beats a isochronic tones.

The technology also provides a processor configured to process the neural correlates of emotional or mental state from the first subject (donor), and to produce or define a stimulation pattern for the second subject (recipient) selectively dependent on a waveform pattern of the neural correlates from the first subject. The processor may also perform a PCA a spatial PCA an independent component analysis (ICA), eigenvalue decomposition, eigenvector-based multivariate analyses, factor analysis, an autoencoder neural network with a linear hidden layer, linear discriminant analysis, network component analysis, nonlinear dimensionality reduction (NLDR), or another statistical method of data analysis.

A signal is presented to a second apparatus, configured to stimulate the second subject (recipient), which may be an open loop stimulation dependent on a non-feedback-controlled algorithm, or a closed loop feedback dependent algorithm. The second apparatus produces a stimulation intended to induce in the second subject (recipient) the desired emotional or mental state).

A typically process performed on the neural correlates is a filtering to remove noise. In some embodiments, noise filters may be provided, for example, at 50 Hz, 60 Hz, 100 Hz, 120 Hz, and additional overtones (e.g., tertiary and higher harmonics). The stimulator associated with the second subject (recipient) would typically perform decoding, decompression, decryption, inverse transformation, modulation, etc.

Alternately, an authentic wave or hash thereof may be authenticated via a blockchain, and thus authenticatable by an immutable record. In some cases, it is possible to use the stored encrypted signal in its encrypted form, without decryption.

Due to different brain sizes, and other anatomical, morphological, and/or physiological differences, dominant frequencies associated with the same emotional or mental state may be different in different subjects. Consequently, it may not be optimal to forcefully impose on the recipient the frequency of the donor that may or may not precisely correspond to the recipients frequency associated with the same emotional or mental state. Accordingly, in some embodiments, the donor's frequency may be used to start the process of inducing the desired emotional or mental state in a recipient. As some point, when the recipient is close to achieving the desired emotional or mental state, the stimulation is either stopped or replaced with neurofeedback allowing the brain of the recipient to find its own optimal frequency associated with the desired emotional or mental state.

In one embodiment the feedback signal from the second subject may be correspondingly encoded as per the source signal, and the error between the two minimized. According to one embodiment the processor may perform a noise reduction distinct from a frequency-band filtering. According to one embodiment the neural correlates are transformed into a sparse matrix, and in the transform domain, components having a high probability of representing noise are masked, while components having a high probability of representing signal are preserved. That is, in some cases, the components that represent modulation that are important may not be known a priori. However, dependent on their effect in inducing the desired response in the second subject (recipient), the “important” components may be identified, and the remainder filtered or suppressed. The transformed signal may then be inverse-transformed and used as a basis for a stimulation signal.

According to another embodiment a method of emotional or mental state modification, e.g., brain entrainment is provided, comprising: ascertaining an emotional or mental state in a plurality of first subjects (donors); acquiring brainwaves of the plurality of first subjects (donors), e.g., using one of EEG and MEG, to create a dataset containing brainwaves corresponding to different emotional or mental states. The database may be encoded with a classification of emotional or mental states, activities, environment, or stimulus patterns, applied to the plurality of first subjects, and the database may include acquired brainwaves across a large number of emotional or mental states, activities, environment or stimulus patterns, for example. In many cases, the database records will reflect a characteristic or dominate frequency of the respective brainwaves.

The record(s) thus retrieved are used to define a stimulation pattern for the second subject (recipient). As a relatively trivial example, a female recipient could be stimulated principally based on records from female donors. Similarly, a child recipient of a certain age could be stimulated principally based on the records from children donors of a similar age. Likewise, various demographic, personality, and/or physiological parameters may be matched to ensure a high degree of correspondence to between the source and target subjects. In the target subject, a guided or genetic algorithm may be employed to select modification parameters from the various components of the signal, which best achieve the desired target state based on feedback from the target subject.

Of course, a more nuanced approach is to process the entirety of the database and stimulate the second subject based on a global brainwave-stimulus model, though this is not required, and also, the underlying basis for the model may prove unreliable or inaccurate. In fact it may be preferred to derive a stimulus waveform from only a single first subject (donor), in order to preserve micro-modulation aspects of the signal, which, as discussed above, have not been fully characterized. However, the selection of the donor(s) need not be static and can change frequently. The selection of donor records may be based on population statistics of other users of the records, i.e., whether or not the record had the expected effect filtering donors whose response pattern correlates highest with a given recipient etc. The selection of donor records may also be based on feedback patterns from the recipient

The process of stimulation typically seeks to target a desired emotional or mental state in the recipient which is automatically or semi-automatically determined or manually entered. In one embodiment the records are used to define a modulation waveform of a synthesized carrier or set of carriers, and the process may include a frequency domain multiplexed multi-subcarrier signal (which is not necessarily orthogonal). A plurality of stimuli may be applied concurrently, through the different subchannels and/or though different stimulator electrodes, electric current stimulators, magnetic field generators, mechanical stimulators, sensory stimulators, etc. The stimulus may be applied to achieve brain entrainment (i.e., synchronization) of the second subject (recipient) with one a more first subjects (donors). If the plurality of donors is mutually entrained, then each will have a corresponding brainwave pattern dependent on the basis of brainwave entrainment. This link between donors may be helpful in determining compatibility between a respective donor and the recipient. For example, characteristic patterns in the entrained brainwaves may be determined, even for different target emotional or mental states, and the characteristic patterns may be correlated to find relatively close matches and to exclude relatively poor matches.

This technology may also provide a basis for a social network, dating site, employment, mission (e.g., space or military), or vocational testing, or other interpersonal environments, wherein people may be matched with each other based on entrainment characteristics. For example, people who efficiently entrain with each other may have better compatibility and, therefore, better marriage, work, or social relationships than those who do not. The entrainment effect need not be limited to emotional or mental states, and may arise across any context.

As discussed above, the plurality of first subjects (donors) may have their respective brainwave patterns stored in separate database records. Data from a plurality of first subjects (donors) is used to train the neural network, which is then accessed by inputting the target stage and/or feedback information, and which outputs a stimulation pattern or parameters for controlling a stimulators). When multiple first subject (donors) form the basis for the stimulation pattern, it is preferred that the neural network output parameters of the stimulation, derived from and comprising features of the brainwave patterns or other neural correlates of the emotional or mental state from the plurality of first subject (donors), which are then used to control a stimulator which, for example, generates its own carrier wave(s) which are then modulated based on the output of the neural network. A trained neural network need not periodically retrieve records, and therefore may operate in a more time continuous manner, rather than the more segmented scheme of record-based control.

In any of the feedback dependent methods, the brainwave patterns or other neural correlates of emotional or mental states may be processed by a neural network, to produce an output that guides or controls the stimulation. The stimulation is, for example, at least one of a light signal, a sound signal, an electric signal, a magnetic field, an olfactory signal, a chemical signal, and a vibration or mechanical stimulus. The process may employ a relational database of emotional or mental states and brainwave patterns, e.g., frequencies/neural correlate waveform patterns associated with the respective emotional or mental states. The relational database may comprise a first table, the first table further comprising a plurality of data records of brainwave patterns, and a second table, the second table comprising a plurality of emotional or mental states, each of the emotional or mental states being linked to at least one brainwave pattern. Data related to emotional or mental states and brainwave patterns associated with the emotional or mental states are stored in the relational database and maintained. The relational database is accessed by receiving queries for selected (existing or desired) emotional or mental states, and data records are returned representing the associated brainwave pattern. The brainwave pattern retrieved from the relational database may then be used for modulating a stimulator seeking to produce an effect selectively dependent on the desired emotional or mental state.

A further aspect of the technology provides a computer apparatus for creating and maintaining a relational database of emotional or mental states and frequencies associated with the emotional or mental state. The computer apparatus may comprise a non-volatile memory for storing a relational database of emotional or mental states and neural correlates of brain activity associated with the emotional or mental states, the database comprising a first table comprising a plurality of data records of neural correlates of brain activity associated with the emotional or mental states, and a second table comprising a plurality of emotional or mental states, each of the emotional or mental states being linked to one a more records in the first table; a processor coupled with the non-volatile memory, and being configured to process relational database queries, which are then used for searching the database; RAM coupled with the processor and the non-volatile memory for temporary holding database queries and data records retrieved from the relational database; and an IO interface configured to receive database queries and deliver data records retrieved from the relational database. A structured query language (SQL) or alternate to SQL (e.g., noSQL) database may also be used to store and retrieve records. A relational database described above maintained and operated by a general-purpose computer, improves the operations of the general-purpose computer by making searches of specific emotional or mental states and brainwaves associated therewith more efficient thereby, inter alia, reducing the demand on computing power.

A further aspect of the technology provides a method of brain entrainment comprising: ascertaining an emotional or mental state in at least one first subject (donor), recording brainwaves of said at least one first subject(donor) using at least one channel of EEG and/or MEG; storing the recorded brainwaves in a physical memory device, retrieving the brainwaves from the memory device, applying a stimulus signal comprising a brainwave pattern derived from at least one-channel of the EEG and/or MEG to a second subject (recipient) via transcranial electrical and/or magnetic stimulation, whereby the emotional or mental state desired by the second subject (recipient) is achieved. The stimulation may be of the same dimension (number of channels) as the EEG a MEG, or a different number of channels, typically reduced. For example, the EEG or MEG may comprise 64, 128 or 256 channels, while the transcranial stimulator may have 32 or fewer channels. The placement of electrodes used for transcranial stimulation may be approximately the same as the placement of electrodes used in recording of EEG or MEG to preserve the topology of the recorded signals and, possibly, use these signals for spatial modulation.

One of the advantages of transforming the data is the ability to select a transform that separates the information of interest represented in the raw data, from noise a other information. Some transforms preserve the spatial and state transition history, and may be used for a more global analysis. Another advantage of a transform is that it can present the information of interest in a form where relatively simple linear a statistical functions of low order may be applied. In some cases, it is desired to perform an inverse transform on the data. For example, if the raw data includes noise, such as 50 or 60 Hz interference, a frequency transform may be performed, followed by a narrow band filtering of the interference and its higher order intermodulation products. An inverse transform may be performed to return the data to its time-domain representation for further processing. (In the case of simple filtering, a finite impulse response (FIR) or infinite impulse response (IIR) filter could be employed). In other cases, the analysis is continued in the transformed domain.

Transforms may be part of an efficient algorithm to compress data for storage or analysis, by making the representation of the information of interest consume fewer bits of information (if in digital form) and/or allow it to be communication using lower bandwidth. Typically, compression algorithms will not be lossless, and as a result, the compression is irreversible with respect to truncated information.

Typically, the transformation(s) and filtering of the signal are conducted using traditional computer logic, according to defined algorithms. The intermediate stages may be stored and analyzed. However, in some cases, neural networks or deep neural networks may be used, convolutional neural network architectures, or even analog signal processing. According to one set of embodiments, the transforms (if any) and analysis are implemented in a parallel processing environment. Such as using an SIMD processor such as a GPU (or GPGPU). Algorithms implemented in such systems are characterized by an avoidance of data-dependent branch instructions, with many threads concurrently executing the same instructions.

EEG signals are analyzed to determine the location (e.g., voxel or brain region) from which an electrical activity pattern is emitted, and the wave pattern characterized. The spatial processing of the EEG signals will typically precede the content analysis, since noise and artifacts may be useful for spatial resolution. Further, the signal from one brain region will typically be noise or interference in the signal analysis from another brain region; so the spatial analysis may represent part of the comprehension analysis. The spatial analysis is typically in the form of a geometrically and/or anatomically-constrained statistical model, employing all of the raw inputs in parallel. For example, where the input data is transcutaneous electroencephalogram information, from 32 EEG electrodes, the 32 input channels, sampled at e.g., 500 sps, 1 ksps or 2 ksps, are processed in a four or higher dimensional matrix, to permit mapping of locations and communication of impulses overtime, space and state.

The matrix processing may be performed in a standard computing environment e.g., an i7-7920HQ, i7-8700K, or i9-7980XE processor, under the Windows 10 operating system, executing MatLab (MathWorks, Wobum Mass.) software platform. Alternately, the matrix processing may be performed in a computer cluster or grid or cloud computing environment. The processing may also employ parallel processing, in either a distributed and loosely coupled environment or asynchronous environment. One preferred embodiment employs a single instruction, multiple data processors, such as a graphics processing unit such as the nVidia CUDA environment or AMD Firepro high-performance computing environment.

Artificial intelligence (AI) and ML methods, such as artificial neural networks, deep neural networks, etc., may be implemented to extract the signals of interest Neural networks act as an optimized statistical classifier and may have arbitrary complexity. A so-called deep neural network having multiple hidden layers may be employed. The processing is typically dependent on labeled training data, such as EEG data, or various processed, transformed, or classified representations of the EEG data. The label represents the emotion, mood, context or state of the subject during acquisition. In order to handle the continuous stream of data represented by the EEG, a recurrent neural network architecture may be implemented. Depending preprocessing before the neural network formal implementations of recurrence may be avoided. A four or more dimensional data matrix may be derived from the traditional spatial-temporal processing of the EEG and fed to a neural network. Since the time parameter is represented in the input data, a neural network temporal memory is not required, though this architecture may require a larger number of inputs. Principal component analysis (PCA, en.wikipedia.org/wiki/Principal_component_analysis), spatial PCA (arxiv.org/pdf/1501.03221v3.pdf, adegenet.r-forge.r-project.org/files/tutorial-spca.pdf, www.ncbi.nlm.nih.gov/pubmed/1510870); and clustering analysis may also be employed (en.wikipedia.org/wiki/Cluster_analysis, see U.S. Pat. Nos. 9,336,302, 9,607,023 and cited references).

In general, a neural network of this type of implementation will, in operation, be able to receive unlabeled EEG data, and produce the output signals representative of the predicted or estimated task, performance, context or state of the subject during acquisition of the unclassified EEG. Of course, statistical classifiers may be used rather than neural networks.

The analyzed EEG, either by conventional processing, neural network processing, or both, serves two purposes. First it permits one to deduce which areas of the brain are subject to which kinds of electrical activity under which conditions. Second, it permits feedback during training of a trainee (assuming proper spatial and anatomical correlates between the trainer and trainee), to help the system achieve the desired state, or as may be appropriate, desired series of states and/or state transitions. According to one aspect of the technology, the applied stimulation is dependent on a measured starting state or status (which may represent a complex context and history dependent matrix of parameters), and therefore the target represents a desired complex vector change. Therefore, this aspect of the technology seeks to understand a complex time-space-brain activity associated with an activity or task in a trainer, and to seek a corresponding complex time-space-brain activity associated with the same activity or task in a trainee, such that the complex time-space-brain activity state in the trainer is distinct from the corresponding state sought to be achieved in the trainee. This permits transfer of training paradigms from qualitatively different persons, in different contexts, and, to some extent, to achieve a different result

The conditions of data acquisition from the trainer will include both task data, and sensory-stimulation data. That is, a preferred application of the system is to acquire EEG data from a trainer or skilled individual, which will then be used to transfer learning, or more likely, learning readiness states, to a naïve trainee. The goal for the trainee is to produce a set of stimulation parameters that will achieve, in the trainee, the corresponding neural activity resulting in the EEG state of the trainer at the time of a preceding the learning of a skill or a task, or performance of the task.

It is noted that EEG is not the only neural or brain activity or state data that may be acquired, and of course any and all such data may be included within the scope of the technology, and therefore EEG is a representative example only of the types of data that may be used. Other types include fMRI, magnetoencephalogram, motor neuron activity, PET, etc.

While mapping the stimulus-response patterns distinct from the task is not required in the trainer, it is advantageous to do so, because the trainer may be available for an extended period, the stimulus of the trainee may influence the neural activity patterns, and it is likely that the trainer will have correlated stimulus-response neural activity patterns with the trainee(s). It should be noted that the foregoing has suggested that the trainer is a single individual, while in practice, the trainer may be a population of trainers a skilled individuals. The analysis and processing of brain activity data may, therefore, be adaptive, both for each respective individual and for the population as a whole.

For example, the system may determine that not all human subjects have common stimulus-response brain activity correlates, and therefore that the population needs to be segregated and clustered. If the differences may be normalized, then a normalization matrix or other correction may be employed. On the other hand, if the differences do not permit feasible normalization, the population(s) may be segmented, with different trainers for the different segments. For example, in some tasks, male brains have different activity patterns and capabilities than female brains. This, coupled with anatomical differences between the sexes, implies that the system may provide gender-specific implementations. Similarly, age differences may provide a rational and scientific basis for segmentation of the population. However, depending on the size of the information base and matrices required, and some other factors, each system may be provided with substantially all parameters required for the whole population, with a user-specific implementation based on a user profile or initial setup, calibration, and system training session.

According to one aspect of the present invention, a source subject is instrumented with sensors to determine localized brain activity during experiencing an event. The objective is to identify regions of the brain involved in processing this response.

The sensors will typically seek to determine neuron firing patterns and brain region excitation patterns, which can be detected by implanted electrodes, transcutaneous electroencephalograms, magnetoencephalograms, fMRI, and other technologies. Where appropriate, transcutaneous EEG is preferred, since this is non-invasive and relatively simple.

The source is observed with the sensors in a quiet state, a state in which he or she is experiencing an event, and various control states in which the source is at rest a engaged in different activities resulting in different states. The data may be obtained for a sufficiently long period of time and over repeated trials to determine the effect of duration. The data may also be a population statistical result and need not be derived from only a single individual at a single time.

The sensor data is then processed using a 4D (or higher) model to determine the characteristic location-dependent pattern of brain activity overtime associated with the state of interest. Where the data is derived from a population with various degrees of arousal, the model maintains this arousal state variable dimension.

A recipient is then prepared for receipt of the mental state. The mental state of the recipient may be assessed. This can include responses to a questionnaire, self-assessment, or other psychological assessment method. Further, the transcutaneous EEG (or other brain activity data) of the recipient may be obtained, to determine the starting state for the recipient as well as activity during experiencing the desired mental state.

In addition, a set of stimuli, such as visual patterns, acoustic patterns, vestibular, smell, taste, touch (light touch, deep touch, proprioception, stretch, hot cold, pain, pleasure, electric stimulation, acupuncture, etc.), vagus nerve (e.g., parasympathetic), are imposed on the subject optionally over a range of baseline brain states, to acquire data defining the effect of individual and various combinations of sensory stimulation on the brain state of the recipient. Population data may also be used for this aspect.

The data from the source or population of sources (see above) may then be processed in conjunction with the recipient or population of recipient data, to extract information defining the optimal sensory stimulation overtime of the recipient to achieve the desired brain state resulting in the desired emotional or mental state.

In general, for populations of sources and recipients, the data processing task is immense. However, the statistical analysis will generally be of a form that permits parallelization of mathematical transforms for processing the data, which can be efficiently implemented using various parallel processors, a common form of which is a SIMD (single instruction, multiple data) processor, found in typical graphics processors (GPUs). Because of the cost-efficiency of GPUs, it is referred to implement the analysis using efficient parallelizable algorithms, even if the computational complexity is nominally greater than a CISC-type processor implementation.

During emotional arousal of the recipient, the EEG pattern may be monitored to determine if the desired state is achieved through the sensory stimulation. A closed loop feedback control system may be implemented to modify the stimulation seeking to achieve the target. An evolving genetic algorithm may be used to develop a user model, which relates the emotional or mental state, arousal and valence, sensory stimulation, and brain activity patterns, both to optimize the current session of stimulation and learning, as well as to facilitate future sessions, where the emotional or mental states of the recipient have further enhanced, and to permit use of the system for a range of emotional or mental states.

The stimulus may comprise a chemical messenger or stimulus to alter the subject's level of consciousness or otherwise alter brain chemistry or functioning. The chemical may comprise a hormone or endocrine analog molecule, (such as adrenocorticotropic hormone (ACTH) (4-11)), a stimulant (such as cocaine, caffeine, nicotine, phenethylamines), a psychoactive drug, psychotropic or hallucinogenic substance (a chemical substance that alters brain function, resulting in temporary changes in perception, mood, consciousness and behavior such as pleasantness (e.g. euphoria) or advantageousness (e.g., increased alertness).

While typically, controlled or “illegal” substances are to be avoided, in some cases, these may be appropriate for use. For example, various drugs may alter the state of the brain to enhance or selectively enhance the effect of the stimulation. Such drugs include stimulants (e.g., cocaine, methylphenidate (Ritalin), ephedrine, phenylpropanolamine, amphetamines), narcotics/opiates (opium, morphine, heroin, methadone, oxymorphine, oxycodone, codeine, fentanyl), hallucinogens (lysergic acid diethylamide (LSD), PCP, MDMA (ecstasy), mescaline, psilocybin, magic mushroom (Psilocybe cubensis), Amanita muscaria mushroom, marijuana/cannabis), Salvia divinorum, diphenhydramine (Benadryl), flexeril, tobacco, nicotine, bupropion (Zyban), opiate antagonists, depressants, gamma aminobutyric acid (GABA) agonists or antagonists, NMDA receptor agonists or antagonists, depressants (e.g., alcohol, Xanax; Valium; Halcion; Librium; other benzodiazepines, Ativan; Klonopin; Amytal; Nembutal; Seconal; Phenobarbital, other barbiturates), psychedelics, disassociatives, and deliriants (e.g., a special class of acetylchdine-inhibitor hallucinogen). For example, Carhart-Harris showed using fMRI that LSD and psilocybin caused synchronization of different parts of the brain that normally work separately by making neurons tire simultaneously. This effect can be used to induce synchronization of various regions of the brain to heighten the emotional state.

It is noted that a large number of substances, natural and artificial, can alter mood or arousal and, as a result may impact emotions or non-target mental states. Typically, such substances will cross the blood-brain barrier, and exert a psychotropic effect. Often, however, this may not be necessary or appropriate. For example, a painful stimulus can alter mood, without acting as a psychotropic drug; on the other hand, a narcotic can also alter mood by dulling emotions. Further, sensory stimulation can induce mood and/or emotional changes, such as smells, sights, sounds, various types of touch and proprioception sensation, balance and vestibular stimulation, etc. Therefore, peripherally acting substances that alter sensory perception or stimulation may be relevant to mood. Likewise, pharmacopsychotropic drugs may alter alertness, perceptiveness, memory, and attention, which may be relevant to task-specific mental state control.

It is an object to provide a method for inducing an emotional state in a subject comprising: determining a desired emotional state; selecting a profile from a plurality of profiles stored in a memory, the plurality of profiles each corresponding to a brain activity pattern of at least one exemplar subject under a respective emotional state (the “source”); and exposing a target subject (the “recipient”) to a stimulus modulated according to the selected profile, wherein the exposure, stimulus, and modulation are adapted to induce, in the target subject the desired emotional state.

The brain activity pattern may be an electroencephalographic brainwave pattern, a magnetoencephalographic brainwave pattern, an electrical brainwave pattern, or a metabolic rate pattern, for example.

The stimulus comprises may visual stimulus, an auditory stimulus; an olfactory stimulus; a tactile stimulus; a proprioceptive stimulus; an electrical stimulus; or a magnetic stimulus.

The desired emotional state is may be happiness, joy, gladness, cheerfulness, bliss, delight ecstasy, optimism, exuberance, merriment, joviality; vivaciousness, pleasure, excitement, sexual arousal, relaxation, harmony, or peace, for example.

The exemplar subject and the target subject may be the same human at different times, or different humans, or different species.

The stimulus may comprise an auditory stimulus adapted to induce binaural beats.

The stimulus may comprise a dynamically changing electromagnetic field adapted synchronize brainwave patterns corresponding to the brain activity pattern of at least one exemplar subject under the desired emotional state.

The selected profile may be derived from measurements of brainwave patterns in the exemplar subject selectively acquired during the desired emotional state.

The selected profile may comprise a model derived from at least spatial, frequency and phase analysis of the measured brainwave patterns.

The stimulus may comprise an auditory or visual stimulus frequency corresponding to a frequency pattern in a brainwave pattern of the exemplar subject.

The target subject may be concurrently exposed to the stimulus and a primary audio or visual presentation which does not induce the desired emotional state, wherein the stimulus does not substantially interfere with the target subject appreciation of the audio or visual presentation.

The method may further comprise recording EEG signals of the exemplar subject in the desired emotional state; decoding at least one of a temporal and a spatial pattern from the recorded EEG signals; and storing the decoded at least one of temporal and spatial pattern in a nonvolatile memory.

The method may further comprise selectively modifying the pattern based on differences between the exemplar subject and the target subject.

The stimulus may comprise applying a spatial electrical stimulation pattern to the target subject via transcranial electrical stimulation (tES) to induce the desired emotional state. The spatial electrical stimulation pattern comprises a direct current or an alternating current. The transcranial electrical stimulation (tES) may be at least one of a transcranial direct current stimulation (tDCS), a transcranial alternating current stimulation (tACS), a transcranial pulsed current stimulation (tPCS) transcranial pulsed current stimulation (tPCS), and a transcranial random noise stimulation (tRNS).

The brain activity pattern of the at least one exemplar subject may comprise a magnetoencephalogram (MEG), and the stimulus comprises applying a spatial magnetic stimulation pattern to the target subject via transcranial magnetic stimulation (tMS) to induce the desired emotional state.

The stimulus may achieve brain entrainment in the target subject.

The method may further comprise determining a second desired emotional state; selecting a second profile from the plurality of profiles stored in a memory; and exposing a target subject to a stimulus modulated according to the selected second profile, wherein the exposure, stimulus, and modulation are adapted to induce, in the target subject the desired second emotional state, the second emotional state being different from the first subsequent state and being induced in succession after the emotional state.

It is another object to provide a method of brainwave entrainment comprising the steps of recording EEG of the brainwaves of a first subject in an emotional state; decoding at least one of a temporal and a spatial pattern from the EEG; storing a representation of the pattern in a non-volatile memory; retrieving said pattern from the non-volatile memory modulating the temporal and spatial patterns on a stimulus signal; and applying the stimulus signal to a second subject. The stimulus signal may be an alternating current and said applying comprises applying the alternating current to the second subject via transcranial alternating current stimulation (tACS) to induce the emotional state.

It is a further object to provide a method of brainwave entrainment comprising the steps of recording EEG of the brainwaves of a first subject in a respective emotional state; decoding at least one of temporal and spatial pattern from the recorded EEG; storing said at least one of temporal and spatial pattern in a non-volatile memory; retrieving said at least one of temporal and spatial pattern from the non-volatile memory; modulating the temporal and spatial patters on a light signal; and projecting the light signal to the second subject to induce the respective emotional state. The light signal may be selected from the group consisting of an ambient light signal, a directional light signal, a laser beam signal, a visible spectrum light signal and an infrared light signal.

It is another object to provide a method of brainwave entrainment comprising the steps of recording EEG of the brainwaves of a first subject in an emotional state; decoding at least one of a temporal and a spatial pattern from the EEG; storing said at least one of the temporal and the spatial pattern in a non-volatile memory; retrieving the at least one of the temporal and the spatial pattern from the non-volatile memory; modulating the temporal and spatial patters on an isotonic sound signal; and projecting the isotonic sound signal to a second subject to induce the emotional state.

A still further object provides a method of brainwave entrainment comprising the steps of recording EEG of the brainwaves of a first subject in an emotional state; decoding temporal frequency pattern from the EEG; storing the decoded temporal frequency pattern in a memory; retrieving the temporal frequency pattern from the memory; computing a first set of frequencies by adding a predetermined delta to the frequencies of the temporal frequency pattern; computing a second set of frequencies by subtracted the delta from the frequencies of the temporal frequency pattern; modulating the first set of frequencies on a first acoustical signal; modulating the second set of frequencies on a second acoustical signal; projecting the first set of frequencies into a first ear of the second subject and projecting the second set of frequencies into a second ear of the second subject thereby producing binaural stimulation to induce the emotional state.

Another object provides a method for modifying an emotional state or mood in a subject comprising: selecting an emotional state a mood profile from a memory, corresponding to a brain activity pattern of at least one exemplar subject in a respective emotional state or mood; and exposing a target subject to a stimulus signal modulated according to the selected emotional state or mood profile, to induce, in the target subject the selected emotional state or mood. The brain activity pattern may be acquired through at least one of an electroencephalogram (EEG) and a magnetoencephalogram (EEG). The stimulus signal may be selected from the group consisting of a light a sound, a touch, a smell, an electric current and a magnetic field. The emotional state or mood may be selected from the group consisting of a state of happiness, a state of joy, a state of gladness, a state of cheerfulness, a state of bliss, a state of delight, a state of ecstasy, a state of optimism, a state of exuberance, a state of merriment, a jovial state, a state of vivaciousness, a state of pleasure, a state of excitement, a state of relaxation, a state of harmony, and a state of peace. The exemplar subject and the target subject may be the same subject at different times or different subjects.

A further object provides a method of brainwave entrainment comprising the steps of recording EEG of a first subject in a positive emotional state; storing a spatial-temporal pattern corresponding to the EEG in a memory; modulating a stimulus pattern according to the spatial-temporal pattern; and stimulating a second subject with the modulated stimulus pattern, to induce the positive emotional state. The modulated stimulus pattern may comprise a binaural audio stimulus. The modulated stimulus pattern may comprise a transcranial electrical stimulation, e.g., a direct current stimulus, an alternating current stimulus, a transcranial direct current stimulation (tDCS), a transcranial alternating current stimulation (tACS), a transcranial pulsed current stimulation (tPCS) transcranial pulsed current stimulation (tPCS), or a transcranial random noise stimulation (tRNS).

It is a still further object to provide a method of brainwave entrainment comprising the steps of modulating a predefined temporal and spatial pattern on a magnetic field; and applying the modulated magnetic field to the brain of a subject via transcranial magnetic stimulation (tMS) to selectively induce an emotional state corresponding to the predefined temporal and spatial pattern.

It is an object to provide a system and method for enhancing emotional response to a stimulus in a subject.

It is another object to provide a system and method for enhancing the experience virtual reality by enhancing the emotional response in a subject.

It is a further object to provide a system and method for enhancing cinematographic experience by enhancing the emotional response in viewers while watching a movie.

It is yet another object to provide a system and method for improving users' interaction with a computer.

It is still another object to provide a system and method for improving users' interaction with a robot.

It is a further object to provide a system and method for accelerating memory-retention and recall by inducing a desired emotional state in a subject.

It is yet another object to provide a system and method for treatment of patients with dementia.

It is an object to provide a system and method for facilitating an emotional state achievement process, compromising: determining a neuronal activity pattern, of a subject while engaged in a respective emotion; processing the determined neuronal activity pattern with at least one automated processor; and subjecting a subject seeking to achieve the respective emotion to a stimulus selected from the group consisting of one or more of a sensory excitation, a peripheral excitation, a transcranial excitation, and a deep brain stimulation, dependent on the processed electromagnetic determined neuronal activity pattern.

It is yet another object to provide a system and method for facilitating a mental process, compromising: determining a neuronal activity pattern of a skilled subject having the mental process; processing the determined neuronal activity pattern with at least one automated processor; and subjecting a subject seeking a corresponding mental process to a stimulus selected from the group consisting of one or more of a sensory excitation, a peripheral excitation, a transcranial excitation, and a deep brain stimulation, dependent on the processed electromagnetic determined neuronal activity pattern.

It is still another object to provide a system and method for improving achieving a mental state, compromising: determining a neuronal activity pattern, of a subject while having the mental state; processing the determined neuronal activity pattern with at least one automated processor; and subjecting a subject seeking to achieve the mental state to a stimulus selected from the group consisting of one or more of a sensory excitation, a peripheral excitation, a transcranial excitation, and a deep brain stimulation, dependent on the processed electromagnetic determined neuronal activity pattern. The mental state is, e.g., an emotional state, a mood, or other subjective state.

It is also an object to provide an apparatus for facilitating control over an emotional state, compromising: an input configured to receive data representing a neuronal activity pattern of a subject while having an emotional state; at least one automated processor, configured to process the determined neuronal activity pattern, to determine neuronal activity patterns selectively associated with the emotional state, configured to subject a subject emotional arousal in control over the emotional state to a stimulus selected from the group consisting of one or more of a sensory excitation, a peripheral excitation, a transcranial excitation, and a deep brain stimulation, dependent on the processed determined neuronal activity pattern.

It is further an object to provide an apparatus for facilitating an emotional skill or emotional learning process, compromising: an input configured to receive data representing a neuronal activity pattern of a subject while engaged in an emotional skill or emotional learning process; at least one automated processor, configured to process the determined neuronal activity pattern, to determine neuronal activity patterns selectively associated with successful learning of the emotional skill or emotional learning process; and a stimulator, configured to subject a subject emotional arousal in the respective emotional skill or emotional learning process to a stimulus selected from the group consisting of one or more of a sensory excitation, a peripheral excitation, a transcranial excitation, and a deep brain stimulation, dependent on the processed determined neuronal activity pattern.

It is also an object to provide an apparatus for inducing of a desired emotional state, compromising: an input configured to receive data representing a neuronal activity pattern of a skilled subject while experiencing the desired emotional state; at least one automated processor, configured to process the determined neuronal activity pattern, to determine neuronal activity patterns selectively associated with the desired emotional state; and a stimulator, configured to subject a recipient desiring to attain the same emotional state to a stimulus selected from the group consisting of one or more of a sensory excitation, a peripheral excitation, a transcranial excitation, and a deep brain stimulation, dependent on the processed determined neuronal activity pattern.

It is a further object to provide a system for influencing a brain electrical activity pattern of a subject during emotional arousal, comprising: an input configured to determine a target brain activity state for the subject dependent on the emotional state; at least one processor, configured to generate a stimulation pattern profile adapted to achieve the target brain activity state for the subject dependent on the emotional state; and a stimulator, configured to output at least one stimulus, proximate to the subject dependent on the generated stimulation pattern profile.

It is yet a further object to provide a system for influencing a brain electrical activity pattern of a subject during experiencing information, comprising: an input configured to determine a target brain activity state for the subject dependent on the nature of the respective information; at least one processor, configured to generate a stimulation pattern profile adapted to achieve the target brain activity state for the subject dependent on the emotion; and a stimulator, configured ID output at least one stimulus, proximate to the subject dependent on the generated stimulation pattern profile.

It is still a further object to provide a system for influencing a brain electrical activity pattern of a subject during a state of emotional arousal, comprising: an input configured to determine a target brain emotional state for the subject dependent on the desired emotional state; at least one processor, configured to generate a stimulation pattern profile adapted to achieve the target brain emotional state for the subject dependent on the emotional state; and a stimulator, configured to output at least one stimulus, proximate to the subject dependent on the generated stimulation pattern profile.

It is a still further object to provide a system for determining a target brain activity state for a subject dependent on an emotion state, comprising: a first monitor, configured to acquire a brain activity of a first subject during the emotion state; at least one first processor, configured to analyze a spatial brain activity state overtime of the first subject and determine spatial brain activity states of the first subject which represent readiness for emotion state; a second monitor, configured to acquire a brain activity of a second subject during performance of a variety of activities, under a variety of stimuli; and at least one second processor, configured to: analyze a spatial brain activity state overtime of the second subject and translate the determined spatial brain activity states of the first subject which represent readiness for the emotion state, into a stimulus pattern for the second subject to achieve a spatial brain activity state in the second subject corresponding to emotion state.

It is a still further object to provide a system for determining a target brain activity state for a subject dependent on an emotion or mood, comprising: a first monitor, configured to acquire a brain activity of a first subject during experiencing the emotion or mood; at least one first processor, configured to analyze a spatial brain activity state overtime of the first subject and determine spatial brain activity states of the first subject which represent the emotion or mood; a second monitor, configured to acquire a brain activity of a second subject during the emotion or mood, under a variety of stimuli; and at least one second processor, configured to: analyze a spatial brain activity state overtime of the second subject and translate the determined spatial brain activity states of the first subject which represent the emotion or mood, into a stimulus pattern for the second subject to achieve a spatial brain activity state in the second subject corresponding to the emotion or mood.

It is a further object to provide a method of enhancing an emotional state of a first subject, the method comprising: recording a second subject's brainwaves EEG while at rest, having the second subject experience or enact an emotionally charged experience to induce an emotional state or mood; recording the second subjects brainwaves EEG while experiencing or enacting said emotionally charged experience; extracting a predominant temporal pattern associated with said emotional state from the recorded brainwaves by comparing them with the brainwaves at rest encoding said temporal pattern as a digital code stored in a tangible media; and using said digital code to modulate the temporal pattern on a signal perceptible to the first subject while said first subject is trying to attain the said emotional state, whereby said perceptible signal stimulates in the second subject brainwaves having said temporal pattern to induce the emotional state or mood.

It is still a further object to provide a method of enhancing an emotional state of a first person, the method comprising: recording a second person's brainwaves or EEG while at rest or prior to achieving a desired emotional state; subjecting having the second person to the performance; recording the second person's brainwaves a EEG while subject to the performance; extracting a predominant temporal pattern associated with said performance from the recorded brainwaves or EEG by comparing them with the brainwaves or EEG at rest or prior to achieving the desired emotional state; encoding said temporal pattern as a digital code stored in a tangible media; and using said digital code to modulate the temporal pattern on a signal perceptible to the first person while said first person is seeking to achieve said desired emotional state, whereby said light signal stimulates in the first subject brainwaves a EEG having said temporal pattern to enhance the achievement of the desired emotional state.

A still further object provides a method of assisted appreciation of art by a first subject, the method comprising: recording a second subject's brainwaves EEG while at rest wherein the second subject is knowledgeable in the art having the second subject experience the art, recording the second subjects brainwaves (e.g., EEG, or MEG) while experiencing the art, extracting a predominant temporal pattern associated with appreciating the art from the recorded brainwaves by comparing them with the brainwaves at rest encoding said temporal pattern as a digital code stored in a tangible media; and using said digital code to modulate the temporal pattern on a signal perceptible to the first subject while the first subject is seeking to appreciate the art, whereby said signal stimulates in the first subject brainwaves having said temporal pattern.

It is another object to provide a computer readable medium, storing therein non-transitory instructions for a programmable processor to perform a process, comprising the computer-implemented steps: synchronizing brain activity data of a subject with at least one event involving the subject, analyzing the brain activity data to determine a selective change in the brain activity data corresponding to an emotional correlate of the event; and determine a stimulation pattern adapted to induce a brain activity having a correspondence to the brain activity data associated with the emotion, based on at least a brain activity model.

The at least one of a sensory excitation, peripheral excitation, and transcranial excitation may be generated based on a digital code. The subjecting of the subject having the emotion or mood to the sensory excitation increases a rate of achieving the emotion in the target subject. Similarly, the subjecting of the subject seeking to achieve the emotion or mood to the sensory excitation increases a rate of achieving the emotion or mood in the target. Likewise, the subjecting of the subject seeking to achieve the respective emotional state to the sensory excitation improves the quality or intensity of the emotional state in the subject.

The method may further comprise determining a neuronal baseline activity of the skilled subject while not engaged in the emotion, a neuronal baseline activity of the subject, a neuronal activity of the skilled subject while engaged in the emotion, and/or a neuronal activity of the subject while engaged in the emotion.

The representation of the processed the determined neuronal activity pattern may be stored in memory. The storage could be on a tangible medium as an analog or digital representation. It is possible to store the representation in a data storage and access system either for a permanent backup or further processing the respective representation. The storage can also be in a cloud storage and/or processing system.

The neuronal activity pattern may be obtained by electroencephalographic, magnetoencephalography, MRI, fMRI, PET, low-resolution brain electromagnetic tomography, or other electrical or nonelectrical means.

The neuronal activity pattern may be obtained by at least one implanted central nervous system (cerebral, spinal) or peripheral nervous system electrode. An implanted neuronal electrode can be either within the peripheral nervous system or the central nervous system. The recording device could be portable a stationary. Either with or without onboard electronics such as signal transmitters and/or amplifiers, etc. The at least one implanted electrode can consist of a microelectrode array featuring more than one recording site. Its main purpose can be for stimulation and/or recoding.

The neuronal activity pattern may be obtained by at least a galvanic skin response. Galvanic skin response a resistance is often also referred as electrodermal activity (EDA), psychogalvanic reflex (PGR), skin conductance response (SCR), sympathetic skin response (SSR) and skin conductance level (SCL) and is the property of the human body that causes continuous variation in the electrical characteristics of the skin.

The stimulus may comprise a sensory excitation. The sensory excitation may by either sensible or insensible. It may be either peripheral or transcranial. It may consist of at least one of a visual, an auditory, a tactile, a proprioceptive, a somatosensory, a cranial nerve, a gustatory, an olfactory, a pain, a compression and a thermal stimulus or a combination of the aforesaid. It can, for example, consist of light flashes either within ambient light or aimed at the subject's eyes, 2D a 3D picture noise, modulation of intensity, within the focus of the subjects eye the visual field or within peripheral sight. Within a video presentation, intensity variations may be provided around a periphery of the presentation, globally throughout a presentation (i.e., modulating a backlight a display intensity), or programmed to modulate a brightness of individual objects.

The stimulus may comprise a peripheral excitation, a transcranial excitation, a sensible stimulation of a sensory input an insensible stimulation of a sensory input a visual stimulus, an auditory stimulus, a tactile stimulus, a proprioceptive stimulus, a somatosensory stimulus, a cranial nerve stimulus, a gustatory stimulus, an olfactory stimulus, a pain stimulus, an electric stimulus, a magnetic stimulus, or a thermal stimulus.

The stimulus may comprise transcranial magnetic stimulation (TMS), cranial electrotherapy stimulation (CES), transcranial direct current stimulation (tDCS), comprise transcranial alternating current stimulation (tACS), transcranial random noise stimulation (tRNS), comprise transcranial pulsed current stimulation (tPCS), pulsed electromagnetic field, or noninvasive or invasive deep brain stimulation (DBS), for example. The stimulus may comprise transcranial pulsed ultrasound (TPU). The stimulus may comprise a cochlear implant stimulus, spinal cord stimulation (SCS) or a vagus nerve stimulation (VNS), or other direct or indirect cranial or peripheral nerve stimulus. The stimulus may comprise or achieve brainwave entrainment. The stimulus may comprise electrical stimulation of the retina, a pacemaker, a stimulation microelectrode array, electrical brain stimulation (EBS), focal brain stimulation (FBS), light sound, vibrations, an electromagnetic wave. The light stimulus may be emitted by at least one of a light bulb, a light emitting diode (LED), and a laser. The signal may be one of a ray of light, a sound wave, and an electromagnetic wave. The signal may be a light signal projected onto the first subject by one of a smart bulb generating ambient light, at least one LED position near the eyes of the first subject and laser generating low-intensity pulses.

The mental state may be associated with learning a performing a skill. The skill may comprise a mental skill, e.g., cognitive, alertness, concentration, attention, focusing, memorization, visualization, relaxation, meditation, speedreading, creative skill, “whole-brain-thinking”, analytical, reasoning, problem-solving, critical thinking, intuitive, leadership, learning, speedreading, patience, balancing, perception, linguistic or language, language comprehension, quantitative, “fluid intelligence”, pain management, skill of maintaining positive attitude, a foreign language, musical, musical composition, writing, poetry composition, mathematical, science, art, visual art, rhetorical, emotional control, empathy, compassion, motivational skill, people, computational, science skill, or an inventorship skill. See, U.S. Patent and Pub. App. Nos. U.S. Pat. Nos. 6,435,878, 5,911,581, and 20090069707. The skill may comprise a motor skill, e.g., fine motor, muscular coordination, walking, running, jumping, swimming, dancing, gymnastics, yoga; an athletic or sports, massage skill, martial arts or fighting, shooting, self-defense; speech, singing, playing a musical instrument, penmanship, calligraphy, drawing, painting, visual, auditory, olfactory, game-playing, gambling, sculptor's, craftsman, massage, or assembly skill. Where a skill is to be enhanced, and an emotion to be achieved (or suppressed), concurrently, the stimulus to the recipient may be combined in such a way as to achieve the result. In some cases, the component is universal, while in others, it is subjective. Therefore, the combination may require adaptation based on the recipient characteristics.

The technology may be embodied in apparatuses for acquiring the brain activity information from the source, processing the brain activity information to reveal a target brain activity state and a set of stimuli, which seek to achieve that state in a recipient, and generating stimuli for the recipient to achieve and maintain the target brain activity state over a period of time and potential state transitions. The generated stimuli may be feedback controlled. A general-purpose computer may be used for the processing of the information, a microprocessor, a FPGA an ASIC, a system-on-a-chip, or a specialized system, which employs a customized configuration to efficiently achieve the information transformations required. Typically, the source and recipient act asynchronously, with the brain activity of the source recorded and later processed. However, real-time processing and brain activity transfer are also possible. In the case of a general purpose programmable processor implementation or portions of the technology, computer instructions may be stored on a nontransient computer readable medium. Typically, the system will have special-purpose components, such as a transcranial stimulator, or a modified audio and/or display system, and therefore the system will not be a general purpose system. Further, even in a general purpose system the operation per se is enhanced according to the present technology.

It is another object to provide a method of teaching one of an emotion-dependent mental skill and a motor skill to a first subject, the method comprising: recording a second subject's brainwaves EEG while at rest, having the second subject perform said one of a mental skill and a motor skill; recording the second subject's brainwaves while performing said one of a mental skill and a motor skill; extracting a predominant temporal pattern associated with said one of a mental skill and a motor skill from the recorded brainwaves by comparing them with the brainwaves at rest, encoding said temporal pattern together with an emotional state targeting stimulus pattern, as a digital code stored in a tangible media; and using said digital code to modulate the temporal pattern on a signal perceptible to the first subject while the first subject is learning said one of a mental and a motor skill, whereby said light signal stimulates in the first subject brainwaves having said temporal pattern to accelerate learning of said one if a mental skill and a motor skill. The emotional state targeting stimulus pattern may be derived from the first subject the second subject or a one or more different subjects. The stimulation pattern may thus be modified from the second subject pattern to bias the first subject toward a desired emotional state.

It is a further object to provide a high-definition transcranial alternating current stimulation (HD-tACS) stimulation of a target, having a stimulation frequency, amplitude pattern, spatial pattern, dependent on an existing set of states in the target, and a set of brainwave patterns from a target engaged in a mood, adapted to improve an emotional state or mood of the recipient.

It is yet another object to provide a system and method for facilitating a mental process, compromising: determining a neuronal activity pattern, of a subject while engaged in an emotional process; processing the determined neuronal activity pattern with at least one automated processor; and subjecting a subject targeting the emotional process to a stimulus selected from the group consisting of one or more of a sensory excitation, a peripheral excitation, a transcranial excitation, and a deep brain stimulation, dependent on the processed electromagnetic determined neuronal activity pattern while the subject is subjected to tES, a psychedelic and/or other pharmaceutical agents.

It is a still further object to provide a method of facilitating a skill learning process, comprising: determining a neuronal activity pattern of a skilled subject while engaged in a respective skill; processing the determined neuronal activity pattern with at least one automated processor; modifying the determined neuronal activity pattern according to an emotional state neuronal activity pattern; and subjecting a subject training in the respective skill to a stimulus selected from the group consisting of one or more of a sensory excitation, a peripheral excitation, a transcranial excitation, and a deep brain stimulation, dependent on the modified processed determined neuronal activity pattern. The transcranial electric stimulation (tES) may be one of transcranial direct current stimulation (DCS), transcranial alternative current stimulation (tACS), and high-definition transcranial alternative current stimulation (tES). The emotional state neuronal activity pattern may be a pattern that increases alertness and focus, for example.

Another object provides a method of facilitating a skill learning process, compromising: determining a respective neuronal activity pattern of a skilled subject while engaged in a respective skill and having an emotional state appropriate for learning the skill and while engaged in the respective skill and not having the emotional state appropriate for learning the skill; processing the determined neuronal activity pattern with at least one automated processor; subjecting a subject training in the respective skill to one of a pharmaceutical agent and a psychedelic agent, and subjecting a subject training in the respective skill to a stimulus selected from the group consisting of one or more of a sensory excitation, a peripheral excitation, a transcranial excitation, and a deep brain stimulation, dependent on the processed determined neuronal activity pattern while engaged in a respective skill and having an emotional state appropriate for learning the skill, and adapting the stimulus based on feedback based on a measurement of a neuronal activity pattern of the subject training in the respective skill to determine an emotional state of the subject training in the respective skill.

It is another object to provide a method of inducing an emotional state in a target subject, comprising determining a desired emotional state; selecting a profile from a plurality of profiles stored in a memory, the plurality of profiles each corresponding to a brain activity pattern of a donor subject having a respective emotional state; and exposing the target subject to at least one stimulus modulated according to the selected profile representing and being adapted to induce, in the target subject, the desired emotional state. The brain activity pattern may be at least one of an electroencephalographic brainwave pattern and a magnetoencephalographic brainwave pattern. The at least one stimulus may stimulate a cranial nerve of the target subject. The at least one stimulus may comprise at least one of a visual stimulus, and an auditory stimulus, a two-channel auditory stimulus adapted to induce binaural beats, at least one of a tactile stimulus and a proprioceptive stimulus, an at least one of a direct electrical current and an alternating electrical current, and/or a magnetic field. The stimulus may comprise at least one of an auditory stimulus and a visual stimulus with a frequency corresponding to at least a frequency pattern in a brainwave pattern of the donor subject.

The desired emotional state may be one of happiness, joy, gladness, cheerfulness, bliss, delight, ecstasy, optimism, exuberance, merriment, joviality; vivaciousness, pleasure, excitement, sexual arousal, relaxation, harmony, and peace.

The target subject may be the same as or different from the donor subject. The target subject may be identical with the donor subject, wherein the brain activity pattern of the donor subject was recorded prior to the exposing the target subject to at least one stimulus.

The at least one stimulus may comprise a dynamically changing electromagnetic field adapted to synchronize the target subject's brainwave pattern with a brainwave pattern of the donor subject having the desired emotional state.

The selected profile may be derived from recording of brainwave patterns of the donor subject selectively acquired during the desired emotional state. The selected profile may comprise a model derived from at least one of a spatial, a frequency and a phase analysis of the recorded brainwave patterns.

The method may further comprise recording EEG signals of the donor subject in the desired emotional state; decoding at least one of a temporal and a spatial pattern from the recorded EEG signals; and storing the decoded at least one of temporal and spatial pattern in a non-volatile memory as at least one profile.

The method may comprise selectively modifying stimulus based on differences between the donor subject from which the profile may be derived, and the target subject.

The stimulus may comprise applying at least one of a temporal and a spatial electrical stimulation pattern to the target subject via transcranial electrical stimulation (TES) to induce the desired emotional state. The transcranial electrical stimulation (TES) may be at least one of a transcranial direct current stimulation (tDCS), an oscillating transcranial direct current stimulation (osc-tDCS), a transcranial alternating current stimulation (tACS), a transcranial pulsed current stimulation (tPCS), and a transcranial random noise stimulation (tRNS).

The profile may be derived from brain activity pattern of the donor subject comprising a magnetoencephalogram (MEG), and the stimulus may comprise applying a spatial magnetic stimulation pattern to the target subject via transcranial magnetic stimulation (TMS) to induce the desired emotional state.

The stimulus may achieve brain entrainment in the target subject.

The method may further comprise determining a second desired emotional state; selecting a second profile from the plurality of profiles stored in a memory; and exposing the target subject to a stimulus modulated according to the selected second profile, representing and being adapted to induce, in the target subject, the second desired emotional state, the second emotional state being different from the emotional state and being induced in succession after the emotional state.

At least one profile may correspond to consensus brain activity pattern of a plurality of donor subjects, each of the plurality of donor subjects having the respective emotional state.

It is a further object to provide a method of brainwave entrainment comprising: recording brainwaves of a first subject in a desired emotional state; decoding at least one of a temporal and a spatial pattern from the brainwaves; storing a representation of the pattern in a memory; retrieving said pattern from the memory; modulating the decoded at least one of the temporal and the spatial pattern on at least one stimulus signal; and applying said at least one stimulus signal to a second subject, to induce the second subject to assume the emotional state. The step of recording brainwaves comprise recording of at least one of electroencephalogram and magnetoencephalogram of the brainwaves. The stimulus signal may be at least one of a direct current and an alternating current, and said applying may comprise applying said at least one of a direct current and an alternating current to the second subject via respectively a transcranial direct current stimulation (tDCS) a transcranial alternating current stimulation (tACS) to induce the desired emotional state.

It is a still further object to provide a method of brainwave entrainment comprising: recording the brainwaves of a first subject in a desired emotional state; decoding at least one of temporal and spatial pattern from the recorded brainwaves; storing said at least one of the temporal and spatial pattern in a memory retrieving said at least one of the temporal and spatial pattern from the memory; modulating the at least one of the temporal and spatial pattern on at least one of a current, a magnetic field, a light signal, and an acoustic signal; and exposing the second subject to the at least one of the current, the magnetic field, the light signal, and the acoustic signal, to induce the desired emotional state.

The step of recording the brainwaves may comprise recording of at least one of an electroencephalogram and a magnetoencephalogram of the brainwaves.

Another object provides a method of recording a desired emotional state from a donor, comprising: determining an emotional state of the donor; if the donor may be in the desired emotional state, recording neural correlates of the emotional state of the donor; analyzing neural correlates of the desired emotional state of the donor to decode at least one of a temporal and a spatial pattern corresponding to the desired emotional state; converting said at least one of a temporal and a spatial pattern corresponding to the desired emotional state into a neurostimulation pattern; and storing the neurostimulation pattern in the nonvolatile memory. The neural correlates may be brainwaves of the donor.

The step of analyzing neural correlates may comprise identifying principal components of the brainwaves. The identifying of principal components may comprise performing one of a principal component analysis (PCA), a curvilinear principal component analysis, an independent component analysis (ICA), a Karhunen-Loève transform (KLT), a singular value decomposition (SVD), and a Factor analysis. The step of analyzing neural correlates may comprise performing a frequency domain analysis. The step of performing the frequency analysis may comprise performing one of a Fourier Transform, a Laplace Transform, a Fourier-Stieltjes transform, a Gelfand transform, time-frequency analysis, a short-time Fourier transform, and a fractional Fourier transform.

The desired emotional state may be one of happiness, joy, gladness, cheerfulness, bliss, delight, ecstasy, optimism, exuberance, merriment, joviality; vivaciousness, pleasure, excitement, sexual arousal, relaxation, harmony, and peace.

The method may further comprise retrieving the neurostimulation pattern from the nonvolatile memory; and stimulating the recipient's brain with at least one stimulus modulated with the neurostimulation pattern to induce the desired emotional state in the recipient.

The at least one stimulus may be one of a direct current, an alternating current, a magnetic field, a light, a sound, a tactile signal and an olfactory signal.

The recipient may be the donor at a point in time subsequent to the time of recording the neural correlates of the emotional state of the donor.

The method may further comprise determining an emotional state of the recipient to confirm that the recipient may be in the desired emotional state. The method may further comprise developing a brain model of the recipient; and adjusting said at least one stimulus in accordance with the model to adjust for the differences between the recipients brain and the donor's brain. The method may further comprise the step of administering a pharmacological agent to the recipient to facilitate response of the recipient to the at least one stimulus to induce the desired emotional state. The method may further comprise performing, by the recipient, a physical exercise in conjunction with the at least one stimulus.

It is another object to provide a relational database of neural correlates of emotional states, comprising a first table storing a plurality of respective emotional states, linked with a second table storing information associated with respective emotional states obtained by: recording neural correlates of the respective emotional state of each of a plurality of donors while in the respective emotional state; decoding from the recorded neural correlates at least one of a temporal and a spatial pattern corresponding to the plurality of respective emotional states; and storing information selectively derived from the at least one of the temporal and the spatial pattern corresponding to the plurality of respective emotional states in the second table. The neural correlates of each respective emotional state may be brainwaves. The recording of neural correlates may be done by using one of an electroencephalogram and a magnetoencephalogram. The relational database may be accessible by receipt of a respective emotional state and responsive by providing information linked to the respective emotional state.

Another object provides a method of increasing emotional emersion in a presentation, comprising: defining a target emotional state associated with at least a portion of the presentation; retrieving a record from a database associated with the target emotional state, derived from recorded neural correlates of donors engaged in the target emotional state; defining a neurostimulation pattern based on the record retrieved from the database; and subjecting a recipient to the defined neurostimulation pattern concurrent with being presented with the at least a portion of the presentation.

The defining a target emotional state associated with at least a portion of the presentation may comprise defining a series of emotional states synchronized with activity or objects depicted in the presentation. The retrieving of the record from the database associated with the target emotional state may comprise retrieving a plurality of records corresponding to the series of emotional states. The defining of the neurostimulation pattern may comprise defining a series of neurostimulation patterns based on the retrieved plurality of records. The subjecting the recipient to the defined neurostimulation pattern concurrent with being presented with the at least a portion of the presentation may comprise subjecting the recipient to the defined series of neurostimulation patterns, temporally synchronized with the portions of presentation, in an order defined by the presentation.

The target emotional state may be defined by an author of the presentation, or automatically derived from the presentation.

The database may be a relational database, having a first table of respective emotional states, and a second table of information relating to neural correlates of the respective emotional states, the first table and the second table being linked together and searchable based on respective emotional state.

At least one record of the database may be derived from recorded neural correlates of a plurality of different donors engaged in a common respective target emotional state. The at least one record may comprise a consensus of the plurality of different donors. The at least one record may comprise a plurality of sub-records, each sub-record being derived from a distinct subpopulation of the plurality of different donors, further comprising determining a characteristic of the recipient and selecting a respective sub-record from the record based on the determined characteristic.

The neurostimulation pattern may be at least one of an electrical current, a magnetic field, a light signal, and an acoustic signal. The neurostimulation pattern may be encoded in the record and/or may be defined by at least one automated processor after retrieving the record, and in selective dependence on at least one characteristic of the recipient. The presentation may comprise an audiovisual presentation, e.g., a virtual reality presentation. The defined neurostimulation pattern may be encoded as at least one of an audio and a visual stimulus within the audiovisual presentation. The defined neurostimulation pattern may be encoded as the at least one of the audio and the visual stimulus within the audiovisual presentation dependent on at least one characteristic of the recipient. The defined neurostimulation pattern may be dependent on automatically generated a manual feedback from the recipient.

Another object provides a system for increasing emotional response to a presentation, comprising: a database comprising a record associated with a target emotional state, the record being derived from recorded neural correlates of at least one donor engaged in the respective target emotional state; at least one input configured to receive an association of the target emotional state with a portion of a presentation; at least one automated processor configured to define a neurostimulation pattern based on the record retrieved from the database; and a neurostimulator, configured to emit the defined neurostimulation pattern concurrent with presentation of the portion of the presentation.

The input may be configured to receive a series of associations of respective target emotional states with respective portions of the presentation, and the neurostimulator may be configured to emit a series of the defined neurostimulation patterns synchronized with the received series of associations of the respective target emotional states with the respective portions of the presentation. The database may be a relational database, having a first table of respective emotional states, and a second table of information relating to neural correlates of the respective emotional states, the first table and the second table being linked together and searchable based on respective emotional state. At least one record may be derived from recorded neural correlates of a plurality of different donors engaged in a common respective target emotional state. The at least one record may comprise a consensus of the plurality of different donors. The at least one record may comprise a plurality of sub-records, each sub-record being derived from a distinct subpopulation of the plurality of different donors, a respective sub-record being selectable from the record based on the determined characteristic. The neurostimulator may be at least one of an electrical current stimulator, a magnetic field stimulator, a light signal stimulator, and an acoustic signal stimulator. The neurostimulation pattern may be encoded in the record, and/or may be defined by the at least one automated processor dependent on the record, and in selective dependence on at least one characteristic of the recipient. The presentation may comprise an audiovisual presentation, e.g., a virtual reality presentation, and optionally the defined neurostimulation pattern may be encoded as at least one of an audio and a visual stimulus within the audiovisual presentation. The defined neurostimulation pattern may be encoded as the at least one of the audio and the visual stimulus within the audiovisual presentation dependent on at least one characteristic of the recipient. The defined neurostimulation pattern may be dependent on automatically or manually generated feedback from the recipient.

Other objects will become apparent from a review of disclosure hereof.

The detailed description is described with reference to the accompanying figures. In the figures, the left-most digit(s) of a reference number identifies the figure in which the reference number first appears. The use of the same reference number in different figures indicates similar or identical items.

FIG. 1 shows the electric activity of a neuron contributing to a brainwave.

FIG. 2 shows transmission of an electrical signal generated by a neuron through the skull, skin and other tissue to be detectable by an electrode transmitting this signal to EEG amplifier.

FIG. 3 shows an illustration of a typical EEG setup with a subject wearing a cup with electrodes connected to the EEG machine, which is, in turn, connected to a computer screen displaying the EEG.

FIG. 4 shows a typical EEG reading.

FIG. 5 shows one second of a typical EEG signal.

FIG. 6 shows main brainwave patterns.

FIGS. 7-13 shows a flowchart according to embodiments of the invention.

FIG. 14 shows a schematic representation of an apparatus according to one embodiment of the invention.

FIG. 15 shows brainwave real-time BOLD (Blood Oxygen Level Dependent) fMRI studies acquired with synchronized stimuli.

FIG. 16 shows Brain Entrainment Frequency Following Response (or FFR).

FIG. 17 shows brainwave entrainment before and after synchronization.

FIG. 18 shows brainwaves during inefficient problem solving and stress.

FIGS. 19 and 20 show how binaural beats work.

FIG. 21 shows Functional Magnetic Resonance Imaging (Mental states may be induced in a subject)

FIG. 22 shows a photo of a brain forming a new idea.

FIG. 23 shows 3D T2 CUBE (SPACE/VISTA) FLAIR & DSI tractography

FIG. 24 shows an EEG tracing.

FIGS. 25-29 show flowcharts according to embodiments of the invention.

FIG. 30 shows human brain anatomy.

FIG. 31 shows a brain map.

FIG. 32 shows an image depicting neuron anatomy.

FIG. 33 shows graphs representing a dimensional view of emotions.

FIG. 34 shows a representation of neural activity with respect to emotional state.

FIGS. 35-41 show flowcharts according to embodiments of the invention.

FIG. 42 shows graphs of tDCS. tRNS, and tACS stimulation patterns.

FIGS. 43 and 44 show representations of tDCS neural stimulation.

FIG. 45 shows a representation of tACS or tRNS neural stimulation.

FIG. 46 shows a representation of intracranial electrode implantation.

FIG. 47 shows a representation of tDCS electrode location.

Hereinafter, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings so that the present disclosure may be readily implemented by those skilled in the art. However, it is to be noted that the present disclosure is not limited to the embodiments but can be embodied in various other ways. In drawings, parts irrelevant to the description are omitted for the simplicity of explanation, and like reference numerals denote like parts through the whole document.

Through the whole document the term “connected to” or “coupled to” that is used to designate a connection or coupling of one element to another element includes both a case that an element is “directly connected or coupled to” another element and a case that an element is “electronically connected or coupled to” another element via still another element. Further, it is to be understood that the term “comprises or includes” and/or “comprising or including” used in the document means that one or more other components, steps, operation and/or existence or addition of elements are not excluded in addition to the described components, steps, operation and/or elements unless context dictates otherwise.

Through the whole document the term “unit” or “module” includes a unit implemented by hardware or software and a unit implemented by both of them. One unit may be implemented by two or more pieces of hardware, and two a more units may be implemented by one piece of hardware.

Other devices, apparatus, systems, methods, features and advantages of the invention will be or will become apparent to one with skill in the art upon examination of the following figures and detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description, be within the scope of the invention, and be protected by the accompanying claims.

The present invention generally relates to enhancing emotional response by a subject in connection with the received information by conveying to the brain of the subject temporal patterns of brainwaves of a second subject who had experienced such emotional response, said temporal pattern being provided non-invasively via light, sound, transcranial direct current stimulation (tDCS), transcranial alternating current stimulation (tDAS) or HD-tACS, transcranial magnetic stimulation (TMS) or other means capable of conveying frequency patterns.

The transmission of the brainwaves can be accomplished through direct electrical contact with the electrodes implanted in the brain or remotely employing light sound, electromagnetic waves and other non-invasive techniques. Light sound, or electromagnetic fields may be used to remotely convey the temporal pattern of prerecorded brainwaves to a subject by modulating the encoded temporal frequency on the light sound or electromagnetic filed signal to which the subject is exposed.

Every activity, mental or motor, and emotion is associated with unique brainwaves having specific spatial and temporal patterns, i.e., a characteristic frequency or a characteristic distribution of frequencies overtime and space. Such waves can be read and recorded by several known techniques, including electroencephalographic (EEG), magnetoencephalography (MEG), exact low-resolution brain electromagnetic tomography (eLORETA), sensory evoked potentials (SEP), fMRI, functional near-infrared spectroscopy (fNIRS), etc. The cerebral cortex is composed of neurons that are interconnected in networks. Cortical neurons constantly send and receive nerve impulses-electrical activity-even during sleep. The electrical or magnetic activity measured by an EEG or MEG (or another device) device reflects the intrinsic activity of neurons in the cerebral cortex and the information sent to it by subcortical structures and the sense receptors.

An EEG electrode mainly detects the neuronal activity in the brain region just beneath it. However, the electrodes receive the activity from thousands of neurons. One square millimeter of cortex surface, for example, has more than 100,000 neurons. It is only when the input to a region is synchronized with electrical activity occurring at the same time that simple periodic waveforms in the EEG become distinguishable.

The spatial and temporal pattern associated with specific brainwaves can be digitized and encoded in software code. It has been observed that “playing back the brainwaves” to another animal a person by providing decoded temporal pattern through transcranial direct current stimulation (tDCS), transcranial alternating current stimulation (tACS), high definition transcranial alternating current stimulation (HD-tDCS), transcranial magnetic stimulation (TMS), or through electrodes implanted in the brain allows the recipient to achieve the emotional or mental state at hand or to increase a speed of achievement. For example, if the brainwaves of a mouse navigated a familiar maze are decoded (by EEG or via implanted electrodes), playing this temporal pattern to another mouse unfamiliar with this maze will allow it to learn to navigate this maze faster.

Similarly, recording brainwaves associated with a specific emotional or mental response of one subject and later “playing back” this response to another subject will induce a similar emotional or mental response in the second subject. More generally, when one animal assumes an emotional or mental state, parts of the brain will have characteristic activity patterns. Further, by “artificially” inducing the same pattern in another animal, the other animal will have the same emotional or mental state, or more easily be induced into that state. The pattern of interest may reside deep in the brain, and thus be overwhelmed in an EEG signal by cortical potentials and patterns. However, techniques other than surface electrode EEG may be used to determine and spatially discriminate deep brain activity, e.g., from the limbic system. For example, various types of magnetic sensors may sense deep brain activity. See, e.g., U.S. Pat. Nos. 9,618,591; 9,261,573; 8,618,799; and 8,593,141.

In some cases, EEGs dominated by cortical excitation patterns may be employed to sense the emotional or mental state, since the cortical patterns may correlate with lower-level brain activity. Note that the determination of a state representation of an emotional or mental need not be performed each time the system is used; rather, once the brain spatial and temporal activity patterns and synchronization states associated with a particular emotional or mental states are determined, those patterns may be used for multiple targets and over time.

Similarly, while the goal is, for example, to trigger the target to assume the same brain activity patterns are the exemplar, this can be achieved in various ways, and these methods of inducing the desired patterns need not be invasive. Further, user feedback, especially in the case of a human emotional or mental state transferee, may be used to tune the process. Finally, using the various senses, especially sight, sound, vestibular, touch, proprioception, taste, smell, vagus afferent, other cranial nerve afferent, etc. can be used to trigger high level mental activity, that in a particular subject achieves the desired metal state, emotion or mood.

Thus, in an experimental subject which may include laboratory scale and/or invasive monitoring, a set of brain electrical activity patterns that correspond to particular emotions a emotional or mental states is determined. Preferably, these are also correlated with surface EEG findings. For the transferee, a stimulation system is provided that is non-hazardous and non-invasive. For example, audiovisual stimulation may be exclusively used. A set of EEG electrodes is provided to measure brain activity, and an adaptive a genetic algorithm scheme is provided to optimize the audiovisual presentation, seeking to induce in the transferee the target pattern found in the experimental subject. After the stimulation patterns, which may be path dependent, are determined, it is likely that these patterns will be persistent, though over longer time periods, there may be some desensitization to the stimulation pattern(s). In some cases, audiovisual stimulation is insufficient, and TMS or other electromagnetic stimulation (superthreshold, or preferably subthreshold) is employed to assist in achieving the desired state and maintaining it for the desired period.

Such technology can be used to significantly enhance the emotional response to viewing photos, reproduction of art, virtual reality, TV, listening to music, reading a book, etc. The user's emotional state may be primed for the secondary stimulation, to enhance the results.

For example, when a movie is filmed, actors get into their roles and experience real emotions. If we record these emotions by recording their brainwaves during acting and later playing them back to viewers or otherwise induce in the viewers the same emotional states, while they are watching the film, this would significantly enhance the experience. As discussed above, the emotional state of an actor may be determined based on a script, facial recognition, explicit statement of the actor, etc., and need not be deciphered from the EEG.

Similarly, while producing virtual reality, we can couple digital files containing video with files of brainwaves of people present during the recording, who see the nature in real time and experience emotions first hand, which would dramatically enhance VR experience.

In another example, a book or an eBook can be coupled with a file of recorded brainwaves of the writer or an experienced actor who is trained to evoke an emotional response while reading a script may provide the stimulus.

One of the challenges of adapting robotic technology and artificial intelligence (AI) is a typical lack of an emotional response by a human subject to a robot a an AI software agent. Using brainwaves can help evoke a positive emotional response in humans while interacting with robots and/or AI agents.

One purpose of this invention is to enhance an emotional response by a subject while engaged in mood. Yet another purpose of this invention is to enhance an emotional response by a subject while engaged in entertainment. Still another purpose of this invention is to enhance an emotional response by a subject while engaged with a robot or an artificial intelligence, another purpose of this invention is to assist a person with recalling a past experience, still another purpose of this invention is to assist a person suffering from a form of dementia to recognize the person's family members and friends.

It may be difficult for many to experience the emotional response to a representation of an experience as to the genuine experience. Looking at a photograph of a Grand Canyon does not elicit the same emotional response as seeing the Grand Canyon itself. Looking at a reproduction of Mona Lisa does not elicit the same emotional response as seeing the original painting in Louvre. An immersive experience achieved through virtual reality (VR) applications goes a long way in simulating the reality, but still falls short of eliciting the emotional response comparable with the one associated with real experience.

Elderly people suffering from Alzheimer's disease or other forms of dementia have difficult recalling their past experiences and recognized family members and friends. While in the early stages of the disease they may have difficulty recalling the person's name or identity, but they still recognize a family member as a loved one responding to seeing a family member with a positive emotion. In later stages, however, the patients no longer feel the emotional response upon seeing a family member and are frightened as if seeing a total stranger.

Recording brainwaves while a person is experiencing a strong emotional response to a genuine experience and later transmitting these recorded brainwaves to another or same individual may help experience stronger emotional response. For example, recording brainwaves of a person seeing for the first time the Grand Canyon and transmitting these brainwaves to another (or the same) person who is viewing a photograph of the Grand Canyon or viewing it through VR glasses would enhance the emotional response of that person and help create more genuine immersive experience. Similarly, recording brainwaves of a person seeing for the first time the original painting of Mona Lisa in the Louvre and transmitting these brainwaves to another (or the same) person who is viewing a reproduction of this painting or on a virtual museum tour of the Louvre viewing it through VR glasses would enhance the emotional response of that person and help create more genuine immersive experience.

In another example, recording brainwaves of a musician playing the music in a concert and transmitting these brainwaves to another person who is listening to a recording of this music would enhance the emotional response of that person and help create more genuine immersive experience.

In a further example, recording brainwaves of actors while acting in movie and transmitting these brainwaves to viewers who are watching the movie in a theater, on a television, on a computer, or through VR glasses would enhance the emotional response of that person and help create more genuine immersive experience.

A further example provides that brainwaves associated with specific emotions may be recorded from actors asked to experience these emotions. A library of brainwaves corresponding to specific emotions can be assembled and used to enhance emotional response, for example, of a gamer playing a computer game, with sequences of emotions triggered in the gamer according to the context or paradigm of the game. There are many applications where such library of brainwaves can be use. Examples include use by law enforcement in helping deescalate a conflict or diffuse a situation by calming down people involved in the conflict or situation. It can be used by health care providers in the hospitals to help patients maintain positive attitude so important to their recovery. It can be used by personnel in psychiatric wards in calming down psychiatric patient without the use of psychotropic medications. It can be used in spas and meditation retreats or by individuals wishing to achieve the relaxation response to induce feeling of peace and calm or, perhaps, even the altered state of consciousness. It can be used by athletes, creative people, scientists and other wishing to get into the “zone” to achieve pick performance a creative inspiration.

In another example, recording brainwaves of a passionate teacher enthusiastically explaining a difficult subject and transmitting these brainwaves to a student who is studying the same subject would enhance the emotional response of that person and help maintain focus, concentration, interest and may even help understand the subject of study.

In a further example, recording brainwaves associated with the emotional response of a person to his family members a friends while in the initial stages of the Alzheimer's disease or another form of dementia and later transmitting these brainwaves to the same person while in a later stages of the disease may help the patient recognize the familiar faces or, at least create a positive emotional response upon seeing family members reducing the fear and anxiety associate with inability to recognize familiar faces typical for the later stages of Alzheimer's disease and dementia.

The transmission of the brainwaves can be accomplished through direct electrical contact with the electrodes implanted in the brain or remotely employing light, sound, electromagnetic waves and other non-invasive techniques.

Light sound or invisible electromagnetic fields may be used to remotely convey the temporal pattern of prerecorded brainwaves to a subject, by modulating the encoded temporal frequency on the light, sound or electromagnetic field signal to which the subject is exposed.

Another embodiment is combining a text with the code encoding the temporal pattern of brainwaves of a person reading the text who has normal or accentuated affect. Say a user is reading a lengthy text (a legal brief or an eBook) on a computer screen. While displaying the text computer monitor (or another light source) generates light frequency corresponding to the temporal pattern of brainwaves of another person reading the same text prerecorded and embedded with the text. The result is speed reading and improved comprehension and retention of the information while achieving the same emotional states as the other person. This may have use in persons with abnormal psyche, who fail to achieve normal emotional response to media.

Employing light, sound or electromagnetic field to remotely convey the temporal pattern of brainwaves (which may be prerecorded) to a subject by modulating the encoded temporal frequency on the light, sound or electromagnetic field signal to which the subject is exposed.

When a group of neurons fires simultaneously, the activity appears as a brainwave. Different brainwave-frequencies are linked to different emotional or mental states in the brain.

The EEG pattern may be derived from another individual or individuals, the same individual at a different time, or an in vivo animal model of the desired metal state. The method may therefore replicate a mental state of a first subject in a second subject. The mental state typically is not a state of consciousness a an idea, but rather a subconscious (in a technical sense) state, representing an emotion, readiness, receptivity, or other state, often independent of particular thoughts or ideas. In essence, a mental state of the first subject (a “trainer” or “donor” who is in a desired mental state) is captured by recording neural correlates of the mental state, e.g., as expressed by brain activity patterns, such as EEG or MEG signals. The neural correlates of the first subject either, as direct or recorded representations, may then be used to control a stimulation of the second subject (a “trainee” or “recipient”), seeking to induce the same brain activity patterns in the second subject (recipient/trainee) as were present in the first subject (donor/trainer) to assist the second subject (recipient/trainee) to attain the desired mental state that had been attained by the donor/trainer. In an alternative embodiment, the signals from the first subject (donor/trainer) being in the first mental state are employed to prevent the second subject (recipient/trainee) from achieving a second mental state, wherein the second mental state is an undesirable one.

The source brain wave pattern may be acquired through multichannel EEG or MEG, from a human in the desired brain state. A computational model of the brain state is difficult to create. However, such a model is not required according to the present technology. Rather, the signals may be processed by a statistical process (e.g., PCA or a related technology), or a statistically trained process (e.g., a neural network). The processed signals preferably retain information regarding signal source special location, frequency, and phase. In stimulating the recipient's brain, the source may be modified to account for brain size differences, electrode locations, etc. Therefore, the preserved characteristics are normalized spatial characteristics, frequency, phase, and modulation patterns.

The normalization may be based on feedback from the target subject, for example based on a comparison of a present state of the target subject and a corresponding state of the source subject, or other comparison of known states between the target and source. Typically, the excitation electrodes in the target subject do not correspond to the feedback electrodes of the electrodes on the source subject. Therefore, an additional type of normalization is required, which may also be based on a statistical or statistically trained algorithm.

According to one embodiment, the stimulation of the second subject is associated with a feedback process, to verify that the second subject has appropriately responded to the stimulation, e.g., has a predefined similarity to the mental state as the first subject, has a mental state with a predefined difference from the first subject, or has a desire change from a baseline mental state. Advantageously, the stimulation may be adaptive to the feedback. In some cases, the feedback may be functional, i.e., not based on brain activity per se, or neural correlates of mental state, but rather physical, psychological, or behavioral effects that may be reported or observed.

The feedback typically is provided to a computational model-based controller for the stimulator, which alters stimulation parameters to optimize the stimulation in dependence on a brain and brain state model applicable to the target.

For example, it is believed that brainwaves represent a form of resonance, where ensembles of neurons interact in a coordinated fashion as a set of coupled or interacting oscillators. The frequency of the wave is related to neural responsivity to neurotransmitters, distances along neural pathways, diffusion limitations, etc., and perhaps pacemaker neurons or neural pathways. That is, the same mental state may be represented by different frequencies in two different individuals, based on differences in the size of their brains, neuromodulators present, physiological differences, etc. These differences may be measured in microseconds or less, resulting in fractional changes in frequency. However, if the stimulus is different from the natural or resonant frequency of the target process, the result may be different from that expected. Therefore, the model-based controller can determine the parameters of neural transmission and ensemble characteristics, vis-à-vis stimulation, and resynthesize the stimulus wave to match the correct waveform, with the optimization of the waveform adaptively determined. This may not be as simple as speeding up or slowing down playback of the signal, as different elements of the various waveforms representing neural correlates of mental state may have different relative differences between subjects. Therefore, according to one set of embodiments, the stimulator autocalibrates for the target, based on a correspondence (error) of a measured response to the stimulation and the desired mental state sought by the stimulation. In cases where the results are chaotic or unpredictable based on existing data, a genetic algorithm may be employed to explore the range of stimulation parameters, and determine the response of the target. In some cases, the target has an abnormal or unexpected response to stimulation based on a model maintained within the system. In this case, when the deviance from the expected response is identified, the system may seek to new model, such as from a model repository that may be on-line, such as through the Internet. If the models are predictable, a translation may be provided between an applicable model of a source or trainer, and the applicable model of the target, to account for differences. In some cases, the desired mental state is relatively universal, such as sleep and awake. In this case, the brain response model may be a statistical model, rather than a neural network or deep neural network type implementation.

Thus, in one embodiment, a hybrid approach is provided, with use of donor-derived brainwaves, on one hand, which may be extracted from the brain activity readings (e.g., EEG or MEG) of the first at least one subject (donor), preferably processed by principal component analysis, or spatial principal component analysis, autocorrelation, or other statistical processing technique (clustering, PCA, etc.) or statistically trained technique (backpropagation of errors, etc.) that separates components of brain activity, which can then be modified or modulated based on high-level parameters, e.g., abstractions. See, ml4a.github.io/ml4a/how_neural_networks_are_trained/. Thus, the stimulator may be programmed to induce a series of brain states defined by name (e.g., emotional or mental state 1, emotional or mental state 2, etc.) or as a sequence of “abstract” semantic labels, icons, or other representations, each corresponding to a technical brain state or sequence of sub-states. The sequence may be automatically defined, based on biology and the system training, and thus relieve the programmer of low-level tasks. However, in a general case, the present technology maintains use of components or subcomponents of the donor's brain activity readings, e.g., EEG or MEG, and does not seek to characterize or abstract them to a semantic level.

According to the present technology, a neural network system or statistical classifier may be employed to characterize the brain wave activity and/or other data from a subject. In addition to the classification or abstraction, a reliability parameter is presented, which predicts the accuracy of the output. Where the accuracy is high, a model-based stimulator may be provided to select and/or parameterize the model, and generate a stimulus for a target subject. Where the accuracy is low, a filtered representation of the signal may be used to control the stimulator, bypassing the model(s). The advantage of this hybrid scheme is that when the model-based stimulator is employed, many different parameters may be explicitly controlled independent of the source subject. On the other hand, where the data processing fails to yield a highly useful prediction of the correct model-based stimulator parameters, the model itself may be avoided, in favor of a direct stimulation type system.

Of course, in some cases, one or more components of the stimulation of the target subject may be represented as abstract or semantically defined signals, and more generally the processing of the signals to define the stimulation will involve high level modulation a transformation between the source signal received from the first subject, to define the target signal for stimulation of the second subject.

Preferably, each component represents a subset of the neural correlates reflecting brain activity that have a high spatial autocorrelation in space and time, a in a hybrid representation such as wavelet. For example, one signal may represent a modulated 10.2 Hz signal, while another signal represents a superposed modulated 15.7 Hz signal, with respectively different spatial origins. These may be separated by optimal filtering, once the spatial and temporal characteristics of the signal are known, and bearing in mind that the signal is accompanied by a modulation pattern, and that the two components themselves may have some weak coupling and interaction.

In some cases, the base frequency, modulation, coupling, noise, phase jitter, a other characteristic of the signal may be substituted. For example, if the first subject is listening to music, there will be significant components of the neural correlates that are synchronized with the particular muse. On the other hand, the music per se may not be part of the desired stimulation of the target subject. Therefore, through signal analysis and decomposition, the components of the signal from the first subject, which have a high temporal correlation with the music, may be extracted or suppressed from the resulting signal. Further, the target subject may be in a different acoustic environment and it may be appropriate to modify the residual signal dependent on the acoustic environment of the target subject, so that the stimulation is appropriate for achieving the desired effect, and does not represent phantoms, distractions, or irrelevant or inappropriate content. In order to perform processing, it is convenient to store the signals or a partially processed representation, though a complete real-time signal processing chain may be implemented. Such a real-time signal processing chain is generally characterized in that the average size of a buffer remains constant, i.e., the lag between output and input is relatively constant, bearing in mind that there may be periodicity to the processing.

The mental state of the first subject may be identified, and the neural correlates of brain activity captured. The second subject is subject to stimulation based on the captured neural correlates and the identified mental state. The mental state may be represented as a semantic variable, within a limited classification space. The mental state identification need not be through analysis of the neural correlates signal, and may be a volitional self-identification by the first subject a manual classification by third parties, or an automated determination. The identified mental state is useful, for example, because it represents a target toward (or against) which the second subject can be steered.

The stimulation may be one or more inputs to the second subject, which may be an electrical or magnetic transcranial stimulation, sensors stimulation, mechanical stimulation, ultrasonic stimulation, etc., and controlled with respect to waveform, intensity/amplitude, duration, feedback, self-reported effect by the second subject, manual classification by third parties, automated analysis of brain activity, behavior, physiological parameters, etc. of the second subject.

The process may be used to induce in the target subject neural correlates of the desired mental state, which are derived from a different time for the same person, or a different person at the same or a different time. For example, one seeks to induce the neural correlates of the first subject in a desired mental state in a second subject, through the use of stimulation parameters comprising a waveform over a period of time derived from the neural correlates of mental state of the first subject.

The first and second subjects may be spatially remote from each other, and may be temporally remote as well. In some cases, the first and second subject are the same animal (e.g., human), temporally displaced. In other cases, the first and second subject are spatially proximate to each other. In some cases, neural correlates of a desired mental state are derived from a mammal having a simpler brain, which are then extrapolated to a human brain. (Animal brain stimulation is also possible, for example to enhance training and performance). When the first and second subjects share a common environment the signal processing of the neural correlates, and especially of real-time feedback of neural correlates from the second subject may involve interactive algorithms with the neural correlates of the first subject.

The first and second subjects may each be subject to stimulators. The first subject and the second subject may communicate with each other in real-time, with the first subject receiving stimulation based on the second subject, and the second subject receiving feedback based on the first subject. This can lead to synchronization of mental state between the two subjects. However, the first subject need not receive stimulation based on real-time signals from the second subject as the stimulation may derive from a third subject or the first or second subjects at different points in time.

The neural correlates may be, for example, EEG, qEEG, or MEG signals. Traditionally, these signals are found to have dominant frequencies, which may be determined by various analyses. One embodiment provides that the modulation pattern of a brainwave of the first subject is determined independent of the dominant frequency of the brainwave (though typically within the same class of brainwaves), and this modulation imposed on a wave corresponding to the dominant frequency of the second subject. That is, once the second subject achieves that same brainwave pattern as the first subject (which may be achieved by means other than electromagnetic, mechanical, or sensors stimulation), the modulation pattern of the first subject is imposed as a way of guiding the mental state of the second subject.

The second subject may be stimulated with a stimulation signal which faithfully represents the frequency composition of a defined component of the neural correlates of the first subject.

The stimulation may be performed, for example, by using a tDCS device, a high-definition tDCS device, a tACS device, a TMS device, a deep TMS device, and a source of one of a light signal and a sound signal configured to modulate the dominant frequency on the one of a light signal and a sound signal. The stimulus may be at least one of a light signal, a sound signal, an electric signal, and a magnetic field. The electric signal may be a direct current signal or an alternating current signal. The stimulus may be a transcranial electric stimulation, a transcranial magnetic stimulation, a deep magnetic stimulation, a light stimulation, or a sound stimulation. A visual stimulus may be ambient light or a direct light. An auditory stimulus may be binaural beats or isochronic tones.

The technology may also provide a processor configured to process the neural correlates of mental state from the first subject and to produce or define a stimulation pattern for the second subject selectively dependent on a waveform pattern of the neural correlates from the first subject. Typically, the processor performs signal analysis and calculates at least a dominant frequency of the brainwaves of the first subject and preferably also spatial and phase patterns within the brain of the first subject.

A signal is presented to a second apparatus, configured to stimulate the second subject, which may be an open loop stimulation dependent on a non-feedback controlled algorithm, or a closed loop feedback dependent algorithm. In other cases, analog processing is employed in part or in whole, wherein the algorithm comprises an analog signal processing chain. The second apparatus receives information from the processor (first apparatus), typically comprising a representation of a portion of a waveform represented in the neural correlates. The second apparatus produces a stimulation intended to induce in the second subject the desired mental state, e.g., representing the same mental state as was present in the first subject.

A typical process performed on the neural correlates is a filtering to remove noise. For example, notch filters may be provided at 50 Hz, 60 Hz, 100 Hz, 120 Hz, and additional overtones. Other environmental signals may also be filtered in a frequency-selective a waveform-selective (temporal) manner. Higher level filtering may also be employed, as is known in the art. The neural correlates, after noise filtering, may be encoded, compressed (lossy or losslessly), encrypted, a otherwise processed a transformed. The stimulator associated with the second subject would typically perform decoding, decompression, decryption, inverse transformation, etc.

Information security and copy protection technology, similar to that employed for audio signals, may be employed to protect the neural correlate signals from copying or content analysis before use. In some cases, it is possible to use the stored encrypted signal in its encrypted for, without decryption. For example, with an asymmetric encryption scheme, which supports distance determination. See U.S. Pat. No. 7,269,277; Sahai and Waters (2005) Annual International Conference on the Theory and Applications of Cryptographic Techniques, pp. 457-473. Springer, Berlin, Heidldberg; Bringer et al. (2009) IEEE International Conference on Communications, pp. 1-6; Juels and Sudan (2006) Designs, Codes and Cryptography 2:237-257; Thaker et al. (2006) IEEE International Conference on Workload Characterization, pp. 142-149; Galil et al. (1987) Conference on the Theory and Application of Cryptographic Techniques, pp. 135-155.

Because the system may act intrusively, it may be desirable to authenticate the stimulator or parameters employed by the stimulator before use. For example, the stimulator and parameters it employs may be authenticated by a distributed ledger, e.g., a blockchain. On the other hand, in a closed system, digital signatures and other hierarchical authentication schemes may be employed. Permissions to perform certain processes may be defined according to smart contracts, which automated permissions (i.e., cryptographic authorization) provided from a blockchain or distributed ledger system. Of course, centralized management may also be employed.

In practice the feedback signal from the second subject may be correspondingly encoded as per the source signal, and the error between the two minimized. In such an algorithm, the signal sought to be authenticated is typically brought within an error tolerance of the encrypted signal before usable feedback is available. One way to accomplish this is to provide a predetermined range of acceptable authenticatable signals which are then encoded, such that an authentication occurs when the putative signal matches any of the predetermined range. In the case of the neural correlates, a large set of digital hash patterns may be provided representing different signals as hash patterns. The net result is relatively weakened encryption, but the cryptographic strength may still be sufficiently high to abate the risks.

The processor may perform a noise reduction distinct from a frequency-band filtering. The neural correlates may be transformed into a sparse matrix, and in the transform domain, components representing high probability noise are masked, while components representing high probability signal are preserved. The distinction may be optimized or adaptive. That is, in some cases, the components which represent modulation that are important may not be known a priori. However, dependent on their effect in inducing the desired response in the second subject the “important” components may be identified, and the remainder filtered or suppressed. The transformed signal may then be inverse-transformed, and used as a basis for a stimulation signal.

A mental state modification, e.g., brain entrainment may be provided, which ascertains a mental state in a plurality of first subjects; acquires brainwaves of the plurality of first subjects, e.g., using one of EEG and MEG, to create a dataset containing representing brainwaves of the plurality of first subjects. The database may be encoded with a classification of mental state, activities, environment or stimulus patterns, applied to the plurality of first subjects, and the database may include acquired brainwaves across a large number of mental states, activities, environment, or stimulus patterns, for example. In many cases, the database records will reflect a characteristic a dominate frequency of the respective brainwaves. As discussed above, the trainer or first subject is a convenient source of the stimulation parameters, but is not the sole available source. The database may be accessed according to its indexing, e.g., mental states, activities, environment, or stimulus patterns, for example, and a stimulation pattern for a second subject defined based on the database records of one or more subjects.

The record(s) thus retrieved are used to define a stimulation pattern for the second subject. The selection of records, and their use, may be dependent on the second subject and/or feedback from the second subject. As a relatively trivial example, a female second subject could be stimulated principally dependent on records from female first subjects. Of course, a more nuanced approach is to process the entirety of the database and stimulate the second subject based on a global brain wave-stimulus model, though this is not required, and also, the underlying basis for the model may prove unreliable or inaccurate. In fact it may be preferred to derive a stimulus waveform from only a single first subject in order to preserve micro-modulation aspects of the signal, which as discussed above have not been fully characterized. However, the selection of the first subject(s) need not be static, and can change frequently. The selection of first subject records may be based on population statistics of other users of the records (i.e., collaborative filtering, i.e., whose response pattern do I correlate highest with? etc.). The selection of first subject records may also be based on feedback patterns from the second user.

The process of stimulation may seek to target a desired mental state in the second subject which is automatically or semi-automatically determined of manually entered. That target then represents a part of the query against the database to select the desired record(s). The selection of records may be a dynamic process, and reselection of records may be feedback dependent.

The records may be used to define a modulation waveform of a synthesized carrier or set of carriers, and the process may include a frequency domain multiplexed multi-subcarrier signal (which is not necessarily orthogonal). A plurality of stimuli may be applied concurrently, through the suffered subchannels and/or though different stimulator electrodes, magnetic field generators, mechanical stimulators, sensory stimulators, etc. The stimuli for the different subchannels or modalities need not be derived from the same records.

The stimulus may be applied to achieve the desired mental state, e.g., brain entrainment of the second subject with one or more first subjects. Brain entrainment is not the only possible outcome of this process. If the plurality of first subjects are mutually entrained, then each will have a corresponding brain wave pattern dependent on the basis of brainwave entrainment. This link between first subject may be helpful in determining compatibility between a respective first subject and the second subject. For example, characteristic patterns in the entrained brainwaves may be determined, even for different target mental states, and the characteristic patterns correlated to find relatively close matches and to exclude relatively poor matches.

This technology may also provide a basis for a social network, dating site, employment or vocational testing, or other interpersonal environments, wherein people may be matched with each other based on entrainment characteristics. For example, people who efficiently entrain with each other may have better social relationships than those who do not. Thus, rather than seeking to match people based on personality profiles, the match could be made based on an ability of each party to efficiently entrain the brainwave pattern of the other party. This enhances non-verbal communication, and assists in achieving corresponding states during activities. This can be assessed by monitoring neural responses of each individual to video, and also by providing a test stimulation based on the other party's brainwave correlates of mental state, to see whether coupling is efficiently achieved. On the other hand, the technology could be used to assist in entrainment when natural coupling is inefficient, or to block coupling where the coupling is undesirable. An example of the latter is hostility; when two people are entrained in a hostile environment emotional escalation ensures. However, if the entrainment is attenuated, undesired escalation may be impeded.

As discussed above, the plurality of first subjects may have their respective brain wave patterns stored in association with separate database records. However, they may also be combined into a more global model. One such model is a neural network or deep neural network. Typically, such a network would have recurrent features. Data from a plurality of first subjects is used to train the neural network, which is then accessed by inputting the target state and/or feedback information, and which outputs a stimulation pattern or parameters for controlling a stimulator. When multiple first subjects form the basis for the stimulation pattern, it is preferred that the neural network output parameters of the stimulation, derived from and comprising features of the brain wave patterns or other neural correlates of mental state from the plurality of first subjects, which are then used to control a stimulator which, for example, generates its own carrier wave(s) which are then modulated based on the output of the neural network. The neural network need not periodically retrieve records, and therefore may operate in a more time-continuous manner, rather than the more segmented scheme of record-based control.

In any of the feedback dependent methods, the brainwave patterns or other neural correlates of mental state may be processed by a neural network, to produce an output that guides or controls the stimulation. The stimulation, is, for example, at least one of a light (visual) signal, a sound signal, an electric signal, a magnetic field, and a vibration or mechanical stimulus, a other sensory input. The fields may be static or dynamically varying.

The process may employ a relational database of mental states and brainwave patterns, e.g., frequencies/neural correlate waveform patterns associated with the respective mental states. The relational database may comprise a first table, the first table further comprising a plurality of data records of brainwave patterns, and a second table, the second table comprising a plurality of mental states, each of the mental states being linked to at least one brainwave pattern. Data related to mental states and brainwave patterns associated with the mental states are stored in the relational database and maintained. The relational database is accessed by receiving queries for selected mental states, and data records are returned representing the associated brainwave pattern. The brainwave pattern retrieved from the relational database may then be used for modulating a stimulator seeking to produce an effect selectively dependent on the mental state at issue.

A computer apparatus may be provided for creating and maintaining a relational database of mental states and frequencies associated with the mental states, the computer apparatus comprising: a non-volatile memory for storing a relational database of mental states and neural correlates of brain activity associated with the mental states, the database comprising a first table, the first table further comprising a plurality of data records of neural correlates of brain activity associated with the mental states, and a second table, the second table comprising a plurality of mental states, each of the mental states being linked to one a more records in the first table; a processor coupled with the non-volatile memory, configured to process relational database queries, which are then used for searching the database; RAM coupled with the processor and the non-volatile memory for temporary holding database queries and data records retrieved from the relational database; and an I/O interface configured to receive database queries and deliver data records retrieved from the relational database. A SQL or noSQL database may also be used to store and retrieve records.

A further aspect of the technology provides a method of brain entrainment comprising: ascertaining a mental state in a first subject; recording brainwaves of the plurality of subjects using at least one channel one of EEG and MEG; storing the recorded brainwaves in a physical memory device; retrieving the brainwaves from the memory device; applying a stimulus signal comprising a brainwave pattern derived from at least one-channel one of the EEG and MEG to a second subject via transcranial stimulation, whereby the mental state desired by the second subject is achieved. The stimulation may be of the same order (number of channels) as the EEG or MEG, or a different number of channels, typically reduced. For example, the EEG a MEG may comprise 128 or 256 channels, while the transcranial stimulator may have 8 or fewer channels. Sensory stimulation of various modalities and patterns may accompany the transcranial stimulation.

The at least one channel may be less than six channels and the placement of electrodes used for transcranial stimulation may be approximately the same as the placement of electrodes used in recording of said one of EEG and MEG.

The present technology may be responsive to chronobiology, and in particular to the subjective sense of time. For a subject, this may be determined volitionally subjectively, but also automatically, for example by judging attention span, using e.g., eye movements, and analyzing persistence of brainwave patterns or other physiological parameters after a discrete stimulus. Further, time-constants of the brain, reflected by delays and phase may also be analyzed. Further, the contingent negative variation (CNV) preceding a volitional act may be used, both to determine (or measure) conscious action timing, and also the time relationships between thought and action more generally.

Typically, brainwave activity is measured with a large number of EEG electrodes, which each receive signals from a small area on the scalp, a in the case of a MEG, by a number of sensitive magnetic field detectors, which are responsive to local field differences. Typically, the brainwave capture is performed in a relatively high number of spatial dimensions, e.g., corresponding to the number of sensors. It is often unfeasible to process the brainwave signals to create a source model, given that the brainwaves are created by billions of neurons, connected through axons, which have long distances. Further, the neurons are generally non-linear, and interconnected. However, a source model is not required.

Various types of artificial intelligence techniques may be exploited to analyze the neural correlates of an emotional or mental state represented in the brain activity data of both the first subject (donor) (or plurality of donors) and the second subject (recipient). The algorithm or implementation need not be the same, though in some cases, it is useful to confirm the approach of the source processing and feedback processing so that the feedback does not achieve or seek a suboptimal target emotional or mental state. However, given the possible differences in conditions, resources, equipment and purpose, there is no necessary coordination of these processes. The artificial intelligence may take the form of neural networks or deep neural networks, though rule/expert-based systems, hybrids, and more classical statistical analysis may be used. In a typical case, an artificial intelligence process will have at least one aspect which is non-linear in its output response to an input signal, and thus at least the principle of linear superposition is violated. Such systems tend to permit discrimination, since a decision and the process of decision-making are, ultimately, non-linear. An artificially intelligent system requires a base of experience or information upon which to train. This can be a supervised (external labels applied to data), unsupervised (self-discrimination of classes), or semi-supervised (a portion of the data is externally labelled).

A self-learning or genetic algorithm may be used to tune the system, including both or either the signal processing at the donor system and the recipient system. In a genetic algorithm feedback-dependent self-learning system, the responsivity of a subject e.g., the target, to various kinds of stimuli may be determined over a stimulus space. This stimulation may be in the context of use, with a specific target emotional or mental state provided, or unconstrained. The stimulator may operate using a library of stimulus patterns, or seek to generate synthetic patterns or modifications of patterns. Over a period of time, the system will learn to map a desired emotional or mental state to optimal context-dependent parameters of the stimulus pattern.

In some cases it may be appropriate to administer a drug or pharmacological agent, such as melatonin, hypnotic or soporific drug, a sedative (e.g., barbiturates, benzodiazepines, nonbenzodiazepine hypnotics, orexin antagonists, antihistamines, general anesthetics, cannabis and other herbal sedatives, methaqualone and analogues, muscle relaxants, opioids) that assists in achieving the target emotional or mental state, and for emotional states and/or dreams, this may include certain psychotropic drugs, such as epinephrine, norepinephrine reuptake inhibitors, serotonin reuptake inhibitors, peptide endocrine hormones, such as oxytocin, ACTH fragments, insulin, etc. Combining a drug with stimulation may reduce the required dose of the drug and the associated side effects of the drug.

The technology may be used to modify or alter a mental state (e.g., from sleep to waking and vice versa) in a subject. Typically, the starting mental state, brain state, or brainwave pattern is assessed, such as by EEG, MEG, observation, stimulus-response amplitude and/or delay, or the like. Of particular interest in uncontrolled environments are automated mental state assessments, which do not rely on human observation or EEG signals, and rather may be acquired through MEG (e.g., SQID, optically-pumped magnetometer), EMG, MMG (magnetomyogram), mechanical (e.g., accelerometer, gyroscope, etc.), data from physiological sensors (e.g., AKG, heartrate, respiration rate, temperature, galvanic skim potential, etc.), or automated camera sensors.

For example, cortical stimulus-response pathways and reflexes may be exercised automatically, to determine their characteristics on a generally continuous basis. These characteristics may include, for example, a delay between stimulus and the observed central (e.g., EEG) or peripheral response (e.g., EMG, limb accelerometer, video). Typically, the same modality will be used to assess the pre-stimulation state, stimulus response, and post-stimulation state, though this is not a limitation.

In order to change the mental state, a stimulus is applied in a way designed to alter the mental state in a desired manner. A state transition table, or algorithm, may be employed to optimize the transition from a starting mental state to a desired mental state. The stimulus may be provided in an open loop (predetermined stimulus protocol) or closed loop (feedback adapted stimulus protocol), based on observed changes in a monitored variable.

Advantageously, a characteristic delay between application of stimulus and determination of response varies with the brain or mental state. For example, some mental states may lead to increased delay a greater variability in delay, while others may lead to decreased or lower variability. Further, some states may lead to attenuation of response, while others may lead to exaggerated response. In addition, different mental states can be associated with qualitatively different responses. Typically, the mere assessment of the brain or mental state should not itself alter the state, though in some cases the assessment and transition influence may be combined. For example, in seeking to assist in achieving a deep sleep state, excitation that disturbs sleep is contraindicated.

In cases where a brainwave pattern is itself determined by EEG (which may be limited to relatively controlled environments), brainwaves representing that pattern represent coherent firing of an ensemble of neurons, defining a phase. One way to change the state is to advance or retard the triggering of the neuronal excitation, which can be a direct a indirect excitation or inhibition, caused, for example, by electrical, magnetic, mechanical, or sensory stimulation. This stimulation may be time-synchronized with the detected (e.g., by EEG) brainwaves, for example with a phase lead or lag with respect to the detected pattern. Further, the excitation can steer the brainwave signal by continually advancing to a desired state, which through the continual phase rotation represents a different frequency. After the desired new state is achieved, the stimulus may cease, or be maintained in a phase-locked manner to hold the desired state.

A predictive model may be used to determine the current mental state, optimal transition to a desired mental state, when the subject has achieved the desired mental state, and how to maintain the desired mental state. The desired mental state itself may represent a dynamic sequence (e.g., stage 1→stage 2→stage 3, etc.), such that the subject's mental state is held for a desired period in a defined condition. Accordingly, the stimulus may be time-synchronized with respect to the measured brainwave pattern.

Direct measurement or determination of brainwaves or their phase relationships is not necessarily required. Rather, the system may determine tremor or reflex patterns. Typically, the reflex patterns of interest involve central pathways, and more preferably brain reflex pathways, and not spinal cord mediated reflexes, which are less dependent on instantaneous brain state. The central reflex patterns can reflect a time delay between stimulation and motor response, an amplitude of motor response, a distribution of response through various afferent pathways, variability of response, tremor or other modulation of motor activity, etc. Combinations of these characteristics may be employed, and different subsets may be employed at different times or to reflect different states. Similar to evoked potentials, the stimulus may be any sense, especially sight, sound, touch/proprioception/pain/etc., though the other senses, such as taste, smell, balance, etc., may also be exercised. A direct electrical or magnetic excitation is also possible. As discussed, the response may be determined through EEG, MEG, or peripheral afferent pathways.

Normalization of brain activity information may be spatial and/or temporal. For example, the EEG electrodes between sessions or for different subject may be in different locations, leading to a distortion of the multichannel spatial arrangement. Further, head size and shape of different individuals is different, and this needs to be normalized and/or encoded as well. The size and shape of the head/skull and/or brain, may also lead to temporal differences in the signals, such as characteristic time delays, resonant or characteristic frequencies, etc.

One way to account for these effects is through use of a time-space transform, such as a wavelet-type transform. It is noted that in a corresponding way that statistical processes are subject to frequency decomposition analysis through Fourier transforms, they are also subject to time-frequency decomposition through wavelet transforms. Typically, the wavelet transform is a discrete wavelet transform (DWT), though more complex and less regular transforms may be employed. As discussed above, principal component analysis (PCA) and spatial PCA may be used to analyze signals, presuming linearity (linear superposition) and statistical independence of components. However, these presumptions technically do not apply to brainwave data, and practically, one would normally expect interaction between brain wave components (non-independence) and lack of linearity (since “neural networks” by their nature are non-linear), defeating use of PCA or spatial PCA unmodified. However, a field of nonlinear dimensionality reduction provides various techniques to permit corresponding analyses under presumptions of non-linearity and non-independence. See:

en.wikipedia.org/wiki/Nonlinear_dimensionality_reduction,

www.image.ucar.edu/pub/toyIV/monahan_5_16.pdf (An Introduction to Nonlinear Principal Component Analysis, Adam Monahan),

Barros, Allan Kandec, and Andrzej Cichocki. “Extraction of specific signals with temporal structure.” Neural computation 13, no. 9 (2001): 1995-2003;

Ewald, Arne. “Novel multivariate data analysis techniques to determine functionally connected networks within the brain from EEG or MEG data” (2014);

Friston, Karl J. “Basic concepts and overview.” SPMcourse, Short course; Crainiceanu, Ciprian M., Ana-Maria Staicu, Shubankar Ray, and Naresh Punjabi. “Statistical inference on the difference in the means of two correlated functional processes: an application to sleep EEG power spectra.” Johns Hopkins University, Dept of Biostatistics Working Papers (2011): 225;

Friston, Karl J., Andrew P. Holmes, Keith J. Worsley, J-P. Poline, Chris D. Frith, and Richard S J Frackowiak. “Statistical parametric maps in functional imaging: a general linear approach.” Human brain mapping 2, no. 4 (1994): 189-210;

Howard et al., “Distinct Variation Pattern Discovery Using Alternating Nonlinear Principal Component Analysis”, IEEE Trans Neural Network Learn Syst. 2018 January; 29(1):156-166. doi: 10.1109/TNNLS.2016.2616145. Epub 2016 Oct. 26 (www.ncbi.nlm.nih.gov/pubmed/27810837);

Hyvärinen, Aapo, and Patrik Hoyer. “Emergence of phase- and shift-invariant features by decomposition of natural images into independent feature subspaces.” Neural computation 12, no. 7 (2000): 1705-1720;

Joliffe, I. T., “Principal Component Analysis, Second Edition”, Springer 2002, cda.psych.uiuc.edu/statistical_learning_course/Joliffe%20I.%20Principal%20Component%20(2ed., Springer, 2002)(518s)_MVsa_.pdf,

Jutten, Christian, and Massoud Babaie-Zadeh. “Source separation: Principles, current advances and applications.” IAR Annu Meet Nancy Fr 110 (2006);

Karl Friston, “Nonlinear PCA: characterizing interactions between modes of brain activity” (www.fil.ion.ucl.ac.uk/˜karl/Nonlinear%20PCA.pdf,2000),

Konar, Amit and Aruna Chakraborty. Emotion recognition: A pattern analysis approach. John Wiley & Sons, 2014; Kohl, Florian. “Blind separation of dependent source signals for MEG sensory stimulation experiments.” (2013);

Lee, Soo-Young. “Blind source separation and independent component analysis: A review.” Neural Information Processing-Letters and Reviews 6, no. 1 (2005): 1-57;

Nonlinear PCA (www.comp.nus.edu.sg/˜cs5240/lecture/nonlinear-pca.pdf),

Nonlinear PCA toolbox for MATLAB (www.nlpca.org),

Nonlinear Principal Component Analysis: Neural Network Models and Applications (pdfs.semanticschoolar.org/9d31/23542031a227d2f4c/402066cf8ebceaeb7a.pdf).

Nonlinear Principal Components Analysis: Introduction and Application (openaccess.leidenuniv.nl/bitstream/handle/1887/12386/Chapter2.pdf?sequence=10, 2007),

Onken, Amo, Jian K. Liu, P P Chamanthi R. Karunasekara, Ioannis Delis, Tim Gollisch, and Stefano Panzeri. “Using matrix and tensor factorizations for the single-trial analysis of population spike trains.” PLoS computational biology 12, no. 11 (2016): e1005189;

Parida, Shantipriya, Satchidananda Dehuri, and Sung-Bae Cho. “Machine Learning Approaches for Cognitive State Classification and Brain Activity Prediction: A Survey.” Current Bioinformatics 10, no. 4 (2015): 344-359;

Saproo, Sameer, Victor Shih, David C. Jangraw, and Paul Sajda. “Neural mechanisms underlying catastrophic failure in human-machine interaction during aerial navigation.” Journal of neural engineering 13, no. 6 (2016): 066005;

Stone, James V. “Blind source separation using temporal predictability.” Neural computation 13, no. 7 (2001): 1559-1574;

Tressoldi, Patrizio, Ludano Pederzdi, Marco Bilucaglia, Patrizio Caini, Pasquale Fedele, Alessandro Ferrini, Simone Melloni, Diana Richeldi, Florentina Richeldi, and Agostino Aocardo. “Brain-to-Brain (Mind-to-Mind) Interaction at Distance: A Confirmatory Study.” (2014). f1000researchdatas3.amazonaws.com/manuscripts/5914/5adbf847-787a-4fc1-ac04-2e1cd61ca972_4336_patrizio_tressoldi_v3.pdf?doi=10.12688/f1000research.4336.3;

Tsiaparas, Nikolaos N. “Wavelet analysis in coherence estimation of electroencephalographic signals in children for the detection of dyslexia-related abnormalities.” PhD diss., 2006.

Valente, Giancarlo. “Separazione cieca di sorgenti in ambienti reali: nuovi algoritmi, applicazioni e implementazioni.” (2006); SAPIENZA, L A “Blind Source Separation in real-world environments: new algorithms, applications and implementations Separazione cieca di sorgenti in ambienti reali: nuovi algoritmi, applicazioni e.”;

Wahlund, Björn, Wlodzimierz Klonowski, Pawel Stepien, Robert Stepien, Tatjana von Rosen, and Dietrich von Rosen. “EEG data, fractal dimension and multivariate statistics.” Journal of Computer Science and Engineering 3, no. 1 (2010): 10-14;

Wang, Yan, Matthew T. Sutherland, Lori L. Sarrfratello, and Akaysha C. Tang. “Single-trial classification of ERPS using second-order blind identification (SOBI).” In Machine Learning and Cybernetics, 2004. Proceedings of 2004 International Conference on, vd. 7, pp. 4246-4251. IEEE, 2004;

Yu, Xianchuan, Dan Hu, and Jindong Xu. Blind source separation: theory and applications. John Wiley & Sons, 2013.

Therefore, statistical approaches are available for separating EEG signals from other signals, and for analyzing components of EEG signals themselves. According to the present invention, various components that might be considered noise in other contexts, e.g., according to prior technologies, such as a modulation pattern of a brainwave, are preserved. Likewise, interactions and characteristic delays between significant brainwave events are preserved. This information may be stored either integrated with the brainwave pattern in which it occurs, or as a separated modulation pattern that can then be recombined with an unmodulated brainwave pattern to approximate the original subject.

According to the present technology, lossy “perceptual” encoding (i.e., functionally optimized with respect to subjective response) of the brainwaves may be employed to process, store and communicate the brainwave information. In a testing scenario, the “perceptual” features may be tested, so that important information is preserved over information that does not strongly correspond to the effective signal. Thus, while one might not know a priori which components represent useful information, a genetic algorithm may empirically determine which features a data reduction algorithms a parameter sets optimize retention of useful information vs. information efficiency. It is noted that subjects may differ in their response to signal components, and therefore the “perceptual” encoding may be subjective with respect to the recipient. On the other hand, different donors may have different information patterns, and therefore each donor may also require individual processing. As a result pairs of donor and recipient may require optimization, to ensure accurate and efficient communication of the relevant information. According to the present invention, sleep/wake mental states and their corresponding patterns are sought to be transferred. In the recipient these patterns have characteristic brainwave patterns. Thus, the donor may be used, under a variety of alternate processing schemes, to stimulate the recipient, and the sleep/wake response of the recipient determined based on objective criteria, such as resulting brainwave patterns or expert observer reports, or subjective criteria, such as recipient self-reporting, survey or feedback. Thus, after a training period, an optimized processing of the donor, which may include filtering, dominant frequency resynthesis, feature extraction, etc., may be employed, which is optimized for both donor and recipient. In other cases, the donor characteristics may be sufficiently normalized, that only recipient characteristics need be compensated. In a trivial case, there is only one exemplar donor, and the signal is oversampled and losslessly recorded, leaving only recipient variation as a significant factor.

Because dominant frequencies tend to have low information content (as compared to the modulation of these frequencies and interrelation of various sources within the brain), one efficient way to encode the main frequencies is by location, frequency, phase, and amplitude. The modulation of a wave may also be represented as a set of parameters. By decomposing the brainwaves according to functional attributes, it becomes possible, during stimulation, to modify the sequence of “events” from the donor, so that the recipient need not experience the same events, in the same order, and in the same duration, as the donor. Rather, a high-level control may select states, dwell times, and transitions between states, based on classified patterns of the donor brainwaves. The extraction and analysis of the brainwaves of the donors, and response of the recipient may be performed using statistical processes, such as principle components analysis (PCA), independent component analysis (ICA), and related techniques; clustering, classification, dimensionality reduction and related techniques; neural networks and other known technologies. These algorithms may be implemented on general purpose CPUs, array processors such as GPUs, and other technologies.

In practice, a brainwave pattern of the first subject may be analyzed by a PCA technique that respects the non-linearity and non-independence of the brainwave signals, to extract the major cyclic components, their respective modulation patterns, and their respective interrelation. The major cyclic components may be resynthesized by a waveform synthesizer, and thus may be efficiently coded. Further, a waveform synthesizer may modify frequencies or relationships of components from the donor based on normalization and recipient characteristic parameters. For example, the brain of the second subject (recipient) may have characteristic classified brainwave frequencies 3% lower than the donor (or each type of wave may be separately parameterized), and therefore the resynthesis may take this difference into account. The modulation patterns and interrelations may then be reimposed onto the resynthesized patterns. The normalization of the modulation patterns and interrelations may be distinct from the underlying major cyclic components, and this correction may also be made, and the normalized modulation patterns and interrelations included in the resynthesis. If the temporal modifications are not equal, the modulation patterns and interrelations may be decimated or interpolated to provide a correct continuous time sequence of the stimulator. The stimulator may include one or more stimulation channels, which may be implemented as electrical, magnetic, auditory, visual, tactile, or other stimulus, and/or combinations.

The stimulator is preferably feedback controlled. The feedback may relate to the brainwave pattern of the recipient and/or context a ancillary biometric basis. For example, if the second subject (recipient) begins to awaken from sleep, which differs from the first subject (donor) sleep pattern, then the stimulator may resynchronize based on this finding. That is, the stimulator control will enter a mode corresponding to the actual state of the recipient and seek to guide the recipient to a desired state from a current state, using the available range and set of stimulation parameters. The feedback may also be used to tune the stimulator, to minimize error from a predicted or desired state of the recipient subject based on the prior and current stimulation.

The control for the stimulator is preferably adaptive, and may employ a genetic algorithm to improve performance overtime. For example, if there are multiple first subjects (donors), the second subject (recipient) may be matched with those donors from whose brainwave signals (or algorithmically modified versions thereof) the predicted response in the recipient is best, and distinguished from those donors from whose brainwave signals the predicted response in the recipient subject poorly corresponds. Similarly, if the donors have brainwave patterns determined over a range of time and context and stored in a database, the selection of alternates from the database may be optimized to ensure best correspondence of the recipient subject to the desired response.

It is noted that a resynthesizer-based stimulator is not required, if a signal pattern from a donor is available that properly corresponds to the recipient and permits a sufficiently low error between the desired response and the actual response. For example, if a donor and a recipient are the same subject at different times, a large database may be unnecessary, and the stimulation signal may be a minimally processed recording of the same subject at an earlier time. Likewise, in some cases, a deviation is tolerable, and an exemplar signal may be emitted, with relatively slow periodic correction. For example, a sleep signal may be derived from a single subject, and replayed with a periodicity of 90 minutes or 180 minutes, such as a light or sound signal, which may be useful in a dormitory setting, where individual feedback is unavailable or unhelpful.

In some cases, it is useful to provide a stimulator and feedback-based controller on the donor. This will better match the conditions of the donor and recipient and further allow determination of not only the brainwave pattern of the donor, but also responsivity of the donor to the feedback. One difference between the donors and the recipients is that in the donor, the natural sleep pattern is sought to be maintained and not interrupted. Thus, the adaptive multi-subject database may include data records from all subject whether selected ab initio as a useful exemplar or not. Therefore, the issue is whether a predictable and useful response can be induced in the recipient from the database record, and if so, that record may be employed. If the record would produce an unpredictable result or a non-useful result the use of that record should be avoided. The predictability and usefulness of the responses may be determined by a genetic algorithm, or other parameter-space searching technology.

FIG. 1 shows the electric activity of a neuron contributing to a brainwave.

FIG. 2 shows transmission of an electrical signal generated by a neuron through the skull, skin and other tissue to be detectable by an electrode transmitting this signal to EEG amplifier.

FIG. 3 shows an illustration of a typical EEG setup with a subject wearing a cup with electrodes connected to the EEG machine, which is, in turn, connected to a computer screen displaying the EEG. FIG. 4 shows a typical EEG reading. FIG. 5 shows one second of atypical EEG signal. FIG. 6 shows main brainwave patterns.

FIG. 7 shows a flowchart according to one embodiment of the invention. Brainwaves from a subject who is in an emotional state are recorded. Brainwaves associated with the emotion are identified. A temporal pattern in the brainwave associated with the emotion is decoded. The decoded temporal pattern is used to modulate the frequency of at least one stimulus. The temporal pattern is transmitted to the second subject by exposing the second subject to said at least one stimulus.

FIG. 8 shows a flowchart according to one embodiment of the invention. Brainwaves in a subject at rest and in an emotional state are recorded, and a brainwave characteristic associated with the emotion is separated by comparing with the brainwaves at rest. A temporal pattern in the brainwave associated with the emotion is decoded and stored. The stored code is used to modulate the temporal pattern on a stimulus, which is transmitted to the second subject by exposing the second subject to the stimulus

FIG. 9 shows a flowchart according to one embodiment of the invention. Brainwaves in a subject in an emotional state are recorded, and a Fourier Transform analysis performed. A temporal pattern in the brainwave associated with the emotion is then decoded and stored. The stored code is then used to modulate the temporal pattern on a stimulus, which is transmitted to the second subject by exposing the second subject to the stimulus.

FIG. 10 shows a flowchart according to one embodiment of the invention. Brainwaves in a plurality of subjects in a respective emotional state are recorded. A neural network is trained on the recorded brainwaves associated with the emotion. After the neural network is defined, brainwaves in a first subject engaged in the emotion are recorded. The neural network is used to recognize brainwaves associated with the emotion. A temporal pattern in the brainwaves associated with the emotion is decoded and stored. The code is used to modulate the temporal pattern on a stimulus. Brainwaves associated with the emotion in a second subject are induced by exposing the second subject to the stimulus

FIG. 11 shows a flowchart according to one embodiment of the invention. Brainwaves in a subject both at rest and in an emotional state are recorded. A brainwave pattern associated with the emotion is separated by comparing with the brainwaves at rest. For example, a filter or optimal filter may be designed to distinguish between the patterns. A temporal pattern in the brainwave associated with the emotion is decoded, and stored in software code, which is then used to modulate the temporal pattern of light which is transmitted to the second subject by exposing the second subject to the source of the light.

FIG. 12 shows a flowchart according to one embodiment of the invention. Brainwaves in a subject at rest and in an emotion are recoded. A brainwave pattern associated with the emotion is separated by comparing with the brainwaves at rest. A temporal pattern in the brainwave associated with the emotion is decoded and stored as a temporal pattern in software code. The software code is used to modulate the temporal pattern on a sound signal. The temporal pattern is transmitted to the second subject by exposing the second subject to the sound signal.

FIG. 13 shows a flowchart according to one embodiment of the invention. Brainwaves in a subject in an emotional state are recorded, and brainwaves selectively associated with the emotion are identified. A pattern, e.g., a temporal pattern, in the brainwave associated with the emotion, is decoded and used to entrain the brainwaves of the second subject.

FIG. 14 shows a schematic representation of an apparatus according to one embodiment of the invention.

FIG. 15 shows brainwave real time BOLD (Blood Oxygen Level Dependent) fMRI studies acquired with synchronized stimuli.

FIG. 16 shows that a desired metal state may be induced in a target individual (e.g., human, animal), by providing selective stimulation according to a temporal pattern, wherein the temporal pattern is correlated with an EEG pattern of the target when in the desired mental state, or represents a transition which represents an intermediate toward achieving the desired mental state. The temporal pattern may be targeted to a discrete spatial region within the brain, either by a physical arrangement of a stimulator, or natural neural pathways through which the stimulation (a its result) passes.

FIG. 17 shows brainwave entrainment before and after synchronization. See, Understanding Brainwaves to Expand our Consciousness, fractalenlightenment.com/14794/spirituality/understanding-brainwaves-to-expand-our-consciousness

FIG. 18 shows brainwaves during inefficient problem solving and stress.

FIGS. 19 and 20 show how binaural beats work. Binaural beats are perceived when two different pure-tone sine waves, both with frequencies lower than 1500 Hz, with less than a 40 Hz difference between them, are presented to a listener dichotically (one through each ear). See, for example, if a 530 Hz pure tone is presented to a subject's right ear, while a 520 Hz pure tone is presented to the subject's left ear, the listener will perceive the auditory illusion of a third tone, in addition to the two pure-tones presented to each ear. The third sound is called a binaural beat, and in this example would have a perceived pitch correlating to a frequency of 10 Hz, that being the difference between the 530 Hz and 520 Hz pure tones presented to each ear. Binaural-beat perception originates in the inferior colliculus of the midbrain and the superior olivary complex of the brainstem, where auditory signals from each ear are integrated and precipitate electrical impulses along neural pathways through the reticular formation up the midbrain to the thalamus, auditory cortex, and other cortical regions.

FIG. 21 shows Functional Magnetic Resonance Imaging (fMRI). FIG. 22 shows a photo of a brain forming a new idea FIG. 23 shows 3D T2 CUBE (SPACE/VISTA) FLAIR & DSI tractography. FIG. 24 shows The EEG activities for a healthy subject during a working memory task.

FIG. 25 shows a flowchart according to one embodiment of the invention. Brainwaves in a subject in an emotional state are recorded. Brainwaves associated with the emotion are identified. A temporal pattern in the brainwave associated with the emotion is extracted. First and second dynamic audio stimuli are generated, whose frequency differential corresponds to the temporal pattern. Binaural beats are provided using the first and the second audio stimuli to stereo headphones worn by the second subject to entrain the brainwaves of the second subject.

FIG. 25 shows a flowchart according to one embodiment of the invention. Brainwaves of a subject engaged in an emotional state are recorded, and brainwaves associated with the emotion identified. A pattern in the brainwave associated with the emotion is identified, having a temporal variation. Two dynamic audio stimuli whose frequency differential corresponds to the temporal variation are generated, and applied as a set of binaural bits to the second subject to entrain the brainwaves of the second subject

FIG. 26 shows a flowchart according to one embodiment of the invention. Brainwaves of a subject in an emotional state are recorded, and brainwaves associated with the emotion identified. A pattern in the brainwave associated with the emotion is identified, having a temporal variation. A series of isochronic tones whose frequency differential corresponds to the temporal variation is generated and applied as a set of stimuli to the second subject to entrain the brainwaves of the second subject See:

FIG. 27 shows a flowchart according to one embodiment of the invention. Brainwaves of a subject in an emotional state are recorded, and brainwaves associated with the emotion identified. A pattern in the brainwave associated with the emotion is identified, having a temporal variation. Two dynamic light stimuli whose frequency differential corresponds to the temporal variation are generated, and applied as a set of stimuli to the second subject wherein each eye sees only one light stimulus, to entrain the brainwaves of the second subject.

FIG. 28 shows a flowchart according to one embodiment of the invention. Brainwaves of a subject in an emotional state are recorded, and brainwaves associated with the emotion identified. A pattern in the brainwave associated with the emotion is identified, having a temporal variation. Two dynamic electric stimuli whose frequency differential corresponds to the temporal variation are generated, and applied as transcranial stimulation to the second subject wherein each electric signal is applied to the opposite side of the subject's head, to entrain the brainwaves of the second subject.

FIG. 29 shows a flowchart according to one embodiment of the invention. Brainwaves of a subject are recorded at rest and in an emotional state. A brainwave associated with the emotion is separated from the remainder of the signal by comparison with the brainwaves at rest. A temporal pattern if the brainwave associated with the emotion is decoded, and stored in software code, in a memory. The software code is then used to modulate a temporal pattern in light which is transmitted to a second subject who is exposed to the light.

FIG. 30 shows picture of brain anatomy. FIG. 31 shows a brain map. FIG. 32 shows an image depicting neuron anatomy. FIG. 33 shows graphs representing a dimensional view of emotions. FIG. 34 shows a representation of neural activity with respect to emotional state.

In one embodiment, as shown in FIG. 35, brainwaves of the first subject (donor) being in a positive emotional state are recorded 10. A temporal and spatial patterns are decoded from the recorded brainwaves 20 and stored in a non-volatile memory 30. At a later time, the temporal and spatial patters are retrieved from the non-volatile memory 40 and modulated on at least one stimulus 50, which is applied to the first subject via noninvasive brain stimulation technique 60 to induce the positive emotional state. The positive emotional state may be one of or a combination of the state of happiness, joy, gladness, cheerfulness, delight, optimism, merriment, jovialness, vivaciousness, pleasure, excitement, sexual arousal, exuberance, bliss, ecstasy, relaxation, harmony peacefulness.

In another embodiment, as shown in FIG. 36, brainwaves of the first subject being in a positive emotional state are recorded using EEG 80. A temporal and spatial patterns are decoded from the EEG 70 and stored in a non-volatile memory 90. At a later time, the temporal and spatial patterns are retrieved from the non-volatile memory 100 and modulated on a direct current 110, which is applied to the first subject via transcranial direct current stimulation (tDCS) 120 to induce the positive emotional state. See FIG. 42.

In further embodiment, as shown in FIG. 37, brainwaves of the first subject being in a positive emotional state are recorded using EEG 130. A temporal and spatial patterns are decoded from the EEG 140 and stored in a non-volatile memory 150. At a later time, the temporal and spatial patters are retrieved from the non-volatile memory 160 and modulated on an alternating current 170, which is applied to the first subject via transcranial alternating current stimulation (tACS) 180 to induce the positive emotional state. It will be understood by a person skilled in the art that transcranial pulsed current stimulation (tPCS), transcranial random noise stimulation (tRNS), a any other type of transcranial electrical stimulation (tES) may be used. See FIGS. 43-47.

In certain embodiments, as shown in FIG. 38, brainwaves of the first subject being in a positive emotional state are recorded using magnetoencephalogram (MEG) 190. A temporal and spatial patterns are decoded from the MEG 200 and stored in a non-volatile memory 210. At a later time, the temporal and spatial patters are retrieved from the non-volatile memory 220 and modulated on a magnetic field 230, which is applied to the second subject via transcranial magnetic stimulation (tMS) 240 to induce the positive emotional state.

In certain embodiments, as shown in FIG. 39, brainwaves of the first subject being in a positive emotional state are recorded using electroencephalogram (EEG) 250. A temporal and spatial patterns are decoded from the EEG 260 and stored in a non-volatile memory 270. At a later time, the temporal and spatial patters are retrieved from the non-volatile memory 280 and modulated on a light signal 290, which is projected to the second subject 300 to induce the positive emotional state. The light signal may be an ambient light, a directed light or a laser beam. The light may be in a visible spectrum or an infrared light. In all embodiments the second subject may the same as the first subject.

In certain embodiments, as shown in FIG. 40, brainwaves of the first subject being in a positive emotional state are recorded using electroencephalogram (EEG) 310. A temporal pattern is decoded from the EEG 320 and stored in a non-volatile memory 330. At a later time, the temporal patter is retrieved from the non-volatile memory 340 and modulated on an isotonic sound signal 350, which is projected to the second subject 360 to induce the positive emotional state. The isotonic sound signal may be imbedded in a music or an ambient noise. The sound may be in an audible spectrum, infrasound or ultrasound.

In certain embodiments, as shown in FIG. 41, brainwaves of the first subject being in a positive emotional state are recorded using electroencephalogram (EEG) 370. A temporal spatial pattern is decoded from the EEG 380 and stored in a non-volatile memory 390. The first set of frequencies is computed by adding a predetermined delta to the frequencies of the temporal frequency pattern 400. The second set of frequencies is computed by subtracting the delta from the frequencies of the temporal frequency pattern 410. The first set of frequencies is modulated on the first acoustical signal 420. The second set of frequencies is modulated on the second acoustical signal 430. The first acoustic signal is played into an ear of the second subject 440. The second acoustic signal is played into another ear of the second subject 450 thereby producing binaural stimulation to induce the positive emotional state. The isotonic sound signal may be imbedded in a music or an ambient noise. The sound may be in an audible spectrum, infrasound or ultrasound.

FIG. 42 shows graphs of tDCS. tRNS, and tACS stimulation patterns. FIGS. 43 and 44 show representations of tDCS neural stimulation. FIG. 45 shows a representation of tACS or tRNS neural stimulation. FIG. 46 shows a representation of intracranial electrode implantation. FIG. 47 shows a representation of tDCS electrode location.

We record EEG of a first person (source) experiencing an emotional arousal while seeing an authentic scenic view of nature (e.g., standing in front of the Grand Canyon, or Niagara Falls, or Giza Pyramids); then decode the dynamic spatial and/or temporal patterns of the EEG and encode them in software. If a second person (recipient) wants to experience the same emotional arousal while viewing a representation (e.g., a painting, a photograph or a video) of the same scenic view, the software with an encoded dynamic temporal pattern is used to drive “smart bulbs” or another source of light and/or sound while the second person is viewing the representation of the scenic view. The result is an enhanced emotional response and a deeper immersive experience. See FIG. 1.

We record EEG of an actor (or actress) while the actor (or actress) is playing a particular role in a film or theatrical production; we then decode the temporal patterns of the EEG and encode them in software. If another person wants to experience enhanced emotional state while watch the same film or a recording of the theatrical production, the software with encoded temporal pattern is used to drive smart bulbs or another source of light and/or sound while the second person is watching the same film or a recording of the theatrical production. The result is an enhanced emotional response and a deeper immersive experience.

We record EEG of a first person (source) experiencing an emotional arousal while engaged in an activity (playing a game, sports, etc.); then decode the dynamic spatial and/or temporal patterns of the EEG and encode them in software coupled with the virtual reality representation of the activity. If a second person (recipient) wants to experience the same emotional arousal while viewing the virtual reality representation of the activity, the software with an encoded dynamic temporal pattern is used to drive a current a current used in transcranial electric a magnetic brain stimulation. The result is an enhanced emotional response and a deeper immersive experience.

A person is reading a book, and during the course of the reading, brain activity, including electrical or magnetic activity, and optionally other measurements, is acquired. The data is processed to determine the frequency and phase, and dynamic changes of brainwave activity, as well as the spatial location of emission. Based on a brain model, a set of non-invasive stimuli, which may include any and all senses, magnetic nerve or brain stimulation, ultrasound, etc., is devised for a subject who is to read the same book. The set of non-invasive stimuli includes not only content-based components, but also emotional response components. The subject is provided with the book to read, and the stimuli are presented to the subject synchronized with the progress through the book. Typically, the book is presented to the subject through an electronic reader device, such as a computer or computing pad, to assist in synchronization. The same electronic reader device may produce the temporal pattern of stimulation across the various stimulus modalities. The result is that the subject will be guided to the same emotional states as the source of the target brain patterns.

In this description, several preferred embodiments were discussed. Persons skilled in the art will, undoubtedly, have other ideas as to how the systems and methods described herein may be used. It is understood that this broad invention is not limited to the embodiments discussed herein. Rather, the invention is limited only by the following claims.

The aspects of the invention are intended to be separable and may be implemented in combination, sub-combination, and with various permutations of embodiments. Therefore, the various disclosure herein, including that which is represented by acknowledged prior art, may be combined, sub-combined and permuted in accordance with the teachings hereof, without departing from the spirit and scope of the invention.

All references and information sources cited herein are expressly incorporated herein by reference in their entirety.

Poltorak, Alexander

Patent Priority Assignee Title
11944709, Aug 15 2014 Tepha, Inc. Self-retaining sutures of poly-4-hydroxybutyrate and copolymers thereof
Patent Priority Assignee Title
3951134, Aug 05 1974 Dorne & Margolin Inc. Apparatus and method for remotely monitoring and altering brain waves
4172014, Jun 05 1978 Bechtel Corporation Control system for a furfural refining unit receiving medium sour charge oil
4296756, Jul 26 1979 CYBER DIAGNOSTICS, INC ; MADDEN, ARCH I Remote pulmonary function tester
4367527, Aug 07 1979 BISELF INTERNATIONAL INC Pocket calculator for the forecasting of temporal cycles
4407299, May 15 1981 CHILDREN S MEDICAL CENTER CORPORATION, THE Brain electrical activity mapping
4408616, May 15 1981 CHILDREN S MEDICAL CENTER CORPORATION, THE Brain electricaL activity mapping
4421122, May 15 1981 CHILDREN S MEDICAL CENTER CORPORATION, THE Brain electrical activity mapping
4437064, May 22 1981 The United States of America as represented by the United States Apparatus for detecting a magnetic anomaly contiguous to remote location by squid gradiometer and magnetometer systems
4493327, Jul 20 1982 CADWELL LABORATORIES, INC Automatic evoked potential detection
4550736, Oct 14 1983 UNIVERSITY OF OTTAWA UNIVERSITE D OTTAWA Movement artifact detector for sleep analysis
4557270, Aug 23 1983 NEW YORK UNIVERSITY, A NY CORP Electroencephalographic system for intra-operative open-heart surgery
4562540, Nov 12 1982 Schlumberger Technology Corporation Diffraction tomography system and methods
4579125, Jan 23 1984 AEQUITRON MEDICAL, INC Real-time EEG spectral analyzer
4583190, Apr 21 1982 DAROX CORPORATION, A DE CORP ; MEDICAL ELECTRONIC DEVELOPMENT & INSTRUMENT COMPANY, D B A MEDICAL INSTRUMENT COMPANY Microcomputer based system for performing fast Fourier transforms
4585011, Oct 14 1983 UNIVERSITY OF OTTAWA UNIVERSITE D OTTAWA Conjugate eye movement detector for sleep analysis
4591787, Dec 22 1982 Siemens Aktiengesellschaft Multi-channel device with SQUIDS and superconducting gradiometers for the measurement of weak magnetic fields produced by various field sources
4594662, Nov 12 1982 Schlumberger Technology Corporation Diffraction tomography systems and methods with fixed detector arrays
4610259, Aug 31 1983 AEQUITRON MEDICAL, INC EEG signal analysis system
4613817, Jul 05 1983 Siemens Aktiengesellschaft Superconducting gradiometer coil system for an apparatus for the multi-channel measurement of weak nonstationary magnetic fields
4649482, Aug 31 1984 BIO-LOGIC SYSTEMS CORP , A CORP OF DE Brain electrical activity topographical mapping
4689559, Nov 13 1984 Sperry Corporation Apparatus and method to reduce the thermal response of SQUID sensors
4693000, Nov 19 1984 Siemens Aktiengesellschaft Method for manufacturing a three-dimensional gradiometer for a device for the single or multi-channel measurement of weak magnetic fields
4700135, Apr 26 1985 Siemens Aktiengesellschaft Apparatus for measuring weak magnetic fields having several gradiometers with associated SQUID array
4705049, Aug 04 1986 Intraoperative monitoring or EP evaluation system utilizing an automatic adaptive self-optimizing digital comb filter
4733180, Apr 26 1985 Siemens Aktiengesellschaft Apparatus for measuring weak magnetic fields having superconducting connections between a squid array and a gradiometer array
4736307, Apr 21 1982 NeuroScience, Inc. Microcomputer-based system for the on-line analysis and topographic display of human brain electrical activity
4736751, Dec 16 1986 EEG Systems Laboratory Brain wave source network location scanning method and system
4744029, Aug 31 1984 Bio-Logic Brain electrical activity analysis and mapping
4749946, Dec 22 1982 Siemens Aktiengesellschaft Device for the multi-channel measurement of weak variable magnetic fields with squids and superconducting gradiometers arranged on a common substrate
4753246, Mar 28 1986 Regents of the University of California, The EEG spatial filter and method
4761611, Apr 26 1985 Siemens Aktiengesellschaft Apparatus for measuring weak magnetic fields having a DC-SQUID array and gradiometer array
4776345, Sep 04 1987 AEQUITRON MEDICAL, INC Interactive determination of sleep stages
4792145, Nov 05 1985 Sound Enhancement Systems, Inc. Electronic stethoscope system and method
4794533, Nov 07 1986 AEQUITRON MEDICAL, INC System activity change indicator
4801882, May 21 1986 Siemens Aktiengesellschaft Thin film SQUID magnetometer for a device for measuring weak magnetic fields
4846190, Aug 23 1983 UNIVERSITY, NEW YORK Electroencephalographic system data display
4862359, Aug 31 1984 Bio-Logic Systems Corporation Topographical mapping of brain functionality from neuropsychological test results
4883067, May 15 1987 NEUROSONICS, INC Method and apparatus for translating the EEG into music to induce and control various psychological and physiological states and to control a musical instrument
4907597, Oct 09 1987 ASPECT MEDICAL SYSTEMS, INC Cerebral biopotential analysis system and method
4913152, Apr 28 1988 The Johns Hopkins University Magnetoencephalograph (MEG) using a multi-axis magnetic gradiometer for localization and tracking of neuromagnetic signals
4924875, Oct 09 1987 ASPECT MEDICAL SYSTEMS, INC Cardiac biopotential analysis system and method
4937525, Aug 13 1986 Siemens Aktiengesellschaft SQUID-magnetometer for measuring weak magnetic fields with gradiometer loops and Josephson tunnel elements on a common carrier
4940058, Jun 09 1986 Cryogenic remote sensing physiograph
4947480, Oct 31 1988 The United States of America as represented by the United States Multichannel signal enhancement
4949725, Jul 01 1988 Bio-Logic Systems Corporation Apparatus and method for displaying electrical activity generated within a living body
4951674, Mar 20 1989 Biomagnetic analytical system using fiber-optic magnetic sensors
4974602, Aug 16 1988 Siemens Aktiengesellschaft Arrangement for analyzing local bioelectric currents in biological tissue complexes
4977505, May 24 1988 ARCH DEVELOPMENT CORPORATION, THE UNIVERSITY OF CHICAGO Means to correlate images from scans taken at different times including means to determine the minimum distances between a patient anatomical contour and a correlating surface
4982157, Sep 22 1988 Siemens Aktiengesellschaft Superconducting gradiometer loop system of a multichannel measuring device
4983912, Mar 29 1989 Siemens Aktiengesellschaft Method for calibrating SQUID gradiometers of an arbitrary order
4996479, Sep 16 1988 Siemens Aktiengesellschaft Magnetometer device with a Dewar vessel for measuring weak magnetic fields
5008622, Dec 21 1989 United States Department of Energy Superconductive imaging surface magnetometer
5010891, Oct 09 1987 ASPECT MEDICAL SYSTEMS, INC Cerebral biopotential analysis system and method
5012190, Oct 22 1987 U S PHILIPS CORPORATION, A CORP OF DE Apparatus for multi-channel measurement of weak magnetic fields with squids and superconducting gradiometers on individual detachable assemblies, and method of manufacture
5020538, Mar 18 1987 Sam Technology, Inc. Low noise magnetoencephalogram system and method
5020540, Oct 09 1987 ASPECT MEDICAL SYSTEMS, INC Cardiac biopotential analysis system and method
5027817, Jun 22 1989 New York University Statistical based display for positron emission tomography scans
5029082, Mar 30 1987 Wide Trade Foundation Ltd. & Export Corporation; China Xiao Feng Technology & Equipment Co.; China National Electronics Import Correlative analysis in multi-domain processing of cardiac signals
5059814, Nov 30 1988 The California Institute of Technology Winner-take-all circuits for neural computing systems
5061680, Jul 31 1989 Biomagnetic Technologies, Inc. Superconducting biomagnetometer with remote pickup coil
5069218, Feb 03 1987 Terumo Kabushiki Kaisha Fetus monitoring apparatus
5070399, Feb 01 1990 Light color and intensity modulation system
5083571, Apr 18 1988 NEW YORK UNIVERSITY, A CORP OF NEW YORK Use of brain electrophysiological quantitative data to classify and subtype an individual into diagnostic categories by discriminant and cluster analysis
5088497, Feb 03 1987 Terumo Kabushiki Kaisha Fetus monitoring apparatus
5092341, Jun 18 1990 Spacelabs Healthcare LLC Surface ECG frequency analysis system and method based upon spectral turbulence estimation
5092835, Jul 06 1990 Brain and nerve healing power apparatus and method
5095270, Aug 16 1989 U S PHILIPS CORPORATION Method of suppressing current distribution noise in a DC SQUID
5105354, Jan 23 1989 NISHIMURA, TOSHIHIRO Method and apparatus for correlating respiration and heartbeat variability
5109862, Mar 19 1990 Del Mar Avionics Method and apparatus for spectral analysis of electrocardiographic signals
5118606, Sep 02 1988 The Regents of the University of California Methods for detecting cellular pathology by assaying spectrin and spectrin breakdown products
5126315, Feb 27 1987 Hitachi, Ltd. High Tc superconducting device with weak link between two superconducting electrodes
5136687, Oct 10 1989 NEUROSCIENCES RESEARCH FOUNDATION, INC , Categorization automata employing neuronal group selection with reentry
5158932, Jul 31 1989 Biomagnetic Technologies, Inc. Superconducting biomagnetometer with inductively coupled pickup coil
5159703, Dec 28 1989 Silent subliminal presentation system
5159928, Nov 22 1989 Method and apparatus for measuring and controlling the level of hormones in an animal circulatory system
5166614, May 25 1989 Hitachi, Ltd. Integrated-type SQUID magnetometer having a magnetic shield, and a multichannel SQUID magnetometer using the same
5187327, Sep 29 1989 Riken Superconducting magnetic shield
5198977, Nov 27 1990 VERITAS PHARMACEUTICALS INC System and method for localization of functional activity in the human brain
5213338, Sep 30 1991 Brain wave-directed amusement device
5215086, May 03 1991 LivaNova USA, Inc Therapeutic treatment of migraine symptoms by stimulation
5218530, Sep 11 1989 Method of displaying and analyzing nonlinear, dynamic brain signals
5224203, Aug 03 1990 ROCKWELL AUTOMATION TECHNOLOGIES, INC On-line process control neural network using data pointers
5230344, Jul 31 1992 Intelligent Hearing Systems Corp. Evoked potential processing system with spectral averaging, adaptive averaging, two dimensional filters, electrode configuration and method therefor
5230346, Feb 04 1992 The Regents of the University of California Diagnosing brain conditions by quantitative electroencephalography
5231988, Aug 09 1991 LivaNova USA, Inc Treatment of endocrine disorders by nerve stimulation
5233517, Apr 30 1990 Early glaucoma detection by Fourier transform analysis of digitized eye fundus images
5241967, Dec 23 1988 Pioneer Electronic Corporation System for evoking electroencephalogram signals
5243281, Dec 21 1990 Neuromag Oy Multi-channel magnetic flux detector comprising a magnetometer modular construction in a vessel containing a cooling medium
5243517, Aug 03 1988 Northrop Grumman Corporation Method and apparatus for physiological evaluation of short films and entertainment materials
5263488, Oct 05 1992 VIASYS HEALTHCARE INC Method and apparatus for localization of intracerebral sources of electrical activity
5265611, Sep 23 1988 Siemens Aktiengellschaft Apparatus for measuring weak, location-dependent and time-dependent magnetic field
5269315, Aug 16 1991 Regents of the University of California, The Determining the nature of brain lesions by electroencephalography
5269325, May 26 1989 YNI LIMITED Analysis of biological signals using data from arrays of sensors
5273038, Jul 09 1990 Computer simulation of live organ
5280791, Nov 19 1991 SLEEP ISORDERS DIAGNOSTIC AND TREATMENT CENTER, LTD , THE Monitor system for determining the sleep stages of a person
5282474, Nov 09 1990 CENTRO DE NEUROCIENCIAS DE CUBA Method and system for the evaluation and visual display of abnormal electromagnetic physiological activity of the brain and the heart
5283523, Mar 11 1991 Siemens Aktiengesellschaft Squid measurement apparatus with a flux transformer having shielding with a discontinuity
5287859, Sep 25 1992 New York University Electroencephalograph instrument for mass screening
5291888, Aug 26 1991 Electrical Geodesics, Inc. Head sensor positioning network
5293187, Feb 05 1992 BioControl Systems, Inc.; BIOCONTROL SYSTEMS, INC A CA CORPORATION Method and apparatus for eye tracking for convergence and strabismus measurement
5299569, May 03 1991 LivaNova USA, Inc Treatment of neuropsychiatric disorders by nerve stimulation
5303705, May 01 1992 Evoked 23NA MR imaging of sodium currents in the brain
5306228, May 05 1992 Brain wave synchronizer
5307807, Mar 15 1991 CENTRO DE NEUROCIENCIAS DE CUBA Method and system for three dimensional tomography of activity and connectivity of brain and heart electromagnetic waves generators
5309095, Dec 21 1990 Neuromag Oy Compact magnetometer probe and an array of them covering the whole human skull for measurement of magnetic fields arising from the activity of the brain
5309917, Sep 12 1991 SEEMEDX, INC System and method of impedance cardiography and heartbeat determination
5309923, Aug 16 1991 The Regents of the University of California Method and apparatus for determining brain activity including the nature of brain lesions by electroencephalography
5311129, Feb 02 1990 STL Systemtechnik Ludwig GmbH Local magnetic field measurement apparatus having gradiometers arranged on non-parallel, non-orthogonal surfaces
5320109, Oct 25 1991 Nellcor Puritan Bennett LLC Cerebral biopotential analysis system and method
5323777, Nov 01 1990 Neuromag Oy Sensor position indicator coils to be used in magnetoencephalographic experiemnts and a means of attaching them to the head
5325862, Mar 26 1993 The United States of America as represented by the Secretary of the Navy; NAVY, THE UNITED STATES OF AMERICA, AS REPRESENTED BY THE SECRETARY OF THE Method and/or system for personal identification and impairment assessment from brain activity patterns
5326745, Feb 27 1987 Hitachi, Ltd. Superconducting device with C-axis orientation perpendicular to current flow
5331970, Sep 07 1990 SAM TECHNOLOGY, INC EEG spatial enhancement method and system
5335657, May 03 1991 LivaNova USA, Inc Therapeutic treatment of sleep disorder by nerve stimulation
5339811, Nov 06 1991 Mitsui Mining & Smelting Co., Ltd.; The Institute of Physical and Chemical Research (Riken) Magnetoencephalograph
5339826, Dec 09 1991 WESTINGHOUSE ELECTRIC CO LLC Method for training material evaluation with method of EEG spectral estimation
5343871, Mar 13 1992 MINDSCOPE INCORPORATED, A CORPORATION OF PA Method and apparatus for biofeedback
5359363, May 13 1991 Sony Corporation Omniview motionless camera surveillance system
5377100, Mar 08 1993 The United States of America as represented by the Administrator of the; UNITED STATES OF AMERICA, THE, AS REPRESENTED BY THE, ADMINISTRATOR NATIONAL AERONAUTICS AND SPACE ADMINISTRATION Method of encouraging attention by correlating video game difficulty with attention level
5384588, May 13 1991 Sony Corporation System for omindirectional image viewing at a remote location without the transmission of control signals to select viewing parameters
5406956, Feb 11 1993 BRAINWAVE SCIENCE INC Method and apparatus for truth detection
5406957, Feb 05 1992 EMTEE ASSOCIATES, L P Electroencephalic neurofeedback apparatus for training and tracking of cognitive states
5409445, May 05 1992 Brain wave synchronizer
5417211, Aug 05 1992 Siemens Aktiengesellschaft Method for the classification of field patterns generated by electrophysiological activities
5418512, Sep 29 1989 Riken Superconducting magnetic shield
5422689, Feb 05 1992 BioControl Systems, Inc. Method and apparatus for eye tracking for convergence and strabismus measurement
5442289, Jul 31 1989 Biomagnetic Technologies, Inc. Biomagnetometer having flexible sensor
5443073, Sep 12 1991 SEEMEDX, INC System and method of impedance cardiography monitoring
5447154, Jul 31 1992 UNIVERSITE JOSEPH FOURIER Method for determining the position of an organ
5447166, Sep 26 1991 Neurocognitive adaptive computer interface method and system based on on-line measurement of the user's mental effort
5458117, Oct 25 1991 Nellcor Puritan Bennett LLC Cerebral biopotential analysis system and method
5458142, Mar 19 1993 Device for monitoring a magnetic field emanating from an organism
5459536, Dec 27 1993 ALCON LABORATORIES, INC Apparatus and method for automated perimetry
5461699, Oct 25 1993 International Business Machines Corporation Forecasting using a neural network and a statistical forecast
5469057, Mar 08 1994 University of New Mexico Method and apparatus for extending the dynamic range of DC-squid measurements using a flux tracking loop
5474082, Jan 06 1993 BRAIN ACTUATED TECHNOLOGIES, INC Brain-body actuated system
5476438, Mar 11 1993 Zentralinstitut fur Biomedizinische Technik Universitat Ulm Method and apparatus for neuromagnetic stimulation
5491492, Feb 05 1992 BioControl Systems, Inc. Method and apparatus for eye tracking for convergence and strabismus measurement
5496798, Mar 17 1992 NGK Insulators, Ltd. Superconducting tube for shielding magnetic fields
5503149, Aug 02 1990 Computer simulation of live organ using arthroscopic and/or laparoscopic data
5513649, Mar 22 1994 Sam Technology, Inc. Adaptive interference canceler for EEG movement and eye artifacts
5515301, Jun 29 1994 General Electric Company Real-time visualization system for multiple time-sampled signals
5522863, Aug 19 1992 NAVY, UNITED STATES OF AMERICA, AS REPRESNETED BY THE SECRETARY Pulsating behavior monitoring and modification system for neural networks
5546943, Dec 09 1994 Stimulating a beneficial human response by using visualization of medical scan data to achieve psychoneuroimmunological virtual reality
5552375, Feb 27 1987 Hitachi, Ltd. Method for forming high Tc superconducting devices
5555889, Jun 20 1990 Cedars-Sinai Medical Center Methods for detecting propensity fibrillation
5568816, Sep 07 1990 Sam Technology, Inc. EEG deblurring method and system for improved spatial detail
5571150, Dec 19 1994 LivaNova USA, Inc Treatment of patients in coma by nerve stimulation
5579241, Jun 29 1994 General Electric Company Real-time acquisition and archiving system for multiple time-sampled signals
5594849, Aug 09 1991 Yale University; Fujitsu Limited Biomedical magnetism imaging apparatus and method
5600243, Sep 07 1993 Silicon Valley Bank Magnetically shielded magnetic sensor with squid and ground plane
5601081, Jun 04 1993 Shimadzu Corporation Method and apparatus for deducing bioelectric current sources
5611350, Feb 08 1996 Method and apparatus for facilitating recovery of patients in deep coma
5617856, Sep 24 1993 Osaka Gas Company Limited Biological information-measuring apparatus
5619995, Nov 12 1991 Motion video transformation system and method
5622168, Nov 18 1992 John L., Essmyer Conductive hydrogels and physiological electrodes and electrode assemblies therefrom
5626145, Mar 20 1996 Lockheed Martin Energy Systems, Inc. Method and apparatus for extraction of low-frequency artifacts from brain waves for alertness detection
5632272, Mar 07 1991 JPMorgan Chase Bank, National Association Signal processing apparatus
5640493, Aug 03 1990 ROCKWELL AUTOMATION TECHNOLOGIES, INC Historical database training method for neural networks
5643325, Jun 20 1990 Cedars-Sinai Medical Center Defibrillator with shock energy based on EKG transform
5649061, May 11 1995 The United States of America as represented by the Secretary of the Army Device and method for estimating a mental decision
5650726, Sep 22 1994 O Y O CORPORATION Emitter for an electromagnetic tomography measurement system which connects a greater number of windings to a magnetic core at low frequencies than at high frequencies
5656937, Jun 07 1995 Silicon Valley Bank Low-noise symmetric dc SQUID system having two pairs of washer coils and a pair of Josephson junctions connected in series
5662109, Dec 14 1990 Method and system for multi-dimensional imaging and analysis for early detection of diseased tissue
5671740, Jun 04 1993 Shimadzu Corporation Method and apparatus for deducing bioelectric current sources
5678561, Jun 20 1990 Cedars-Sinai Medical Center Methods for detecting propensity for fibrillation
5682889, Jun 04 1993 Shimadzu Corporation Method and apparatus for deducing bioelectric current sources
5685313, May 31 1994 VITAL MEDICAL LTD Tissue monitor
5692517, Jan 06 1993 Brain-body actuated system
5694939, Oct 03 1995 The United States of America as represented by the Administrator of the Autogenic-feedback training exercise (AFTE) method and system
5699808, Feb 07 1994 New York University EEG operative and post-operative patient monitoring system and method
5701909, Nov 01 1994 Abratech Corporation Machine and method for the determination of nervous-system-generator parameters using lead fields
5706402, Nov 29 1994 The Salk Institute for Biological Studies Blind signal processing system employing information maximization to recover unknown signals through unsupervised minimization of output redundancy
5706811, Nov 30 1994 Director-General of Agency of Industrial Science and Technology Method and apparatus for setting reference point for organic measurement
5711305, Feb 17 1995 EP Technologies, Inc. Systems and methods for acquiring endocardially or epicardially paced electrocardiograms
5715821, Dec 09 1994 Biofield Corp Neural network method and apparatus for disease, injury and bodily condition screening or sensing
5719561, Oct 25 1995 GONZALES, GILBERT RENE Tactile communication device and method
5720619, Apr 24 1995 Interactive computer assisted multi-media biofeedback system
5722418, Aug 30 1993 Method for mediating social and behavioral processes in medicine and business through an interactive telecommunications guidance system
5724987, Sep 26 1991 Sam Technology, Inc. Neurocognitive adaptive computer-aided training method and system
5729046, Feb 27 1987 Hitachi, Ltd. Superconducting device having pinning regions
5730146, Aug 01 1991 Transmitting, analyzing and reporting EEG data
5736543, Apr 03 1996 The Regents of the University of California; Cortex Pharmaceuticals, Inc. Benzoxazines for enhancing synaptic response
5737485, Mar 07 1995 Rutgers The State University of New Jersey Method and apparatus including microphone arrays and neural networks for speech/speaker recognition systems
5740812, Jan 25 1996 NEUROTEK, LLC Apparatus for and method of providing brainwave biofeedback
5742748, Jul 14 1995 Virtual reality mental conditioning medium
5743854, Mar 29 1994 CALIFORNIA, THE UNIVERSITY OF, REGENTS OF, THE Method and apparatus for inducing and localizing epileptiform activity
5743860, Mar 20 1996 Lockheed Martin Energy Systems, Inc. Apparatus and method for epileptic seizure detection using non-linear techniques
5747492, Jul 23 1993 The Regents of the University of California Heteroatom substituted benzoyl derivatives that enhance synaptic responses mediated by ampa receptors
5752514, Aug 31 1995 Shimadzu Corporation Biomagnetism measuring method and apparatus
5752521, Nov 12 1993 LIFEWAVES INTERNATIONAL, INC Therapeutic exercise program
5752911, Apr 27 1995 Electromagnetic method of treatment of epilepsy and apparatus
5755227, Jun 04 1993 Shimadzu Corporation Method and apparatus for deducing bioelectric current sources
5755739, Dec 04 1996 Medtronic, Inc. Adaptive and morphological system for discriminating P-waves and R-waves inside the human body
5761332, Mar 11 1995 U.S. Philips Corporation Method of reconstructing the surface of an object
5762611, Nov 12 1996 The United States of America as represented by the Secretary of the Navy; NAVY, UNITED STATES OF AMERICA, THE, AS REPRESENTED BY THE SECRETARY Evaluation of a subject's interest in education, training and other materials using brain activity patterns
5767043, Feb 21 1995 Silicon Valley Bank Multiple squid direct signal injection device formed on a single layer substrate
5771261, Sep 13 1995 Telethermometric psychological evaluation by monitoring of changes in skin perfusion induced by the autonomic nervous system
5771893, Sep 06 1994 Kabushiki Kaisha Toshiba Method and apparatus for nuclear magnetic resonance imaging of physiological function information
5771894, Jun 05 1995 Vanderbilt University Non invasive identification of intestinal ischemia from measurement of basic electrical rhythm of intestinal smooth muscle electrical activity using a magnetometer
5771897, Apr 08 1996 SITNIKOV, L Method of and apparatus for quantitative evaluation of current changes in a functional state of human organism
5791342, Sep 03 1996 Telediagnostics Systems, Inc.; TELEDIAGNOSTIC SYSTEMS, INC Medical data transmission system
5794623, Sep 27 1996 Agilent Technologies Inc Intramyocardial Wenckebach activity detector
5795304, Mar 26 1997 DREXEL UNIVERSITY, A PA CORP System and method for analyzing electrogastrophic signal
5797840, Sep 14 1994 Ramot University Authority for Applied Research & Industrial Development Apparatus and method for time dependent power spectrum analysis of physiological signals
5797853, Mar 31 1994 BRAIN FUNCTIONS LABORATORY, INC Method and apparatus for measuring brain function
5810737, Nov 12 1993 LIFEWAVES INTERNATIONAL, INC Chronotherapy exercise technique
5813993, Apr 05 1996 Consolidated Research of Richmond, Inc.; CONSOLIDATED RESEARCH OF RICHMOND, INC Alertness and drowsiness detection and tracking system
5815413, May 08 1997 Lockheed Martin Energy Research Corporation Integrated method for chaotic time series analysis
5816247, Jun 13 1995 RDM CONSULTANTS LTD Monitoring an EEG
5825830, Aug 17 1995 Method and apparatus for the compression of audio, video or other data
5827195, May 09 1997 SPACELABS HEALTHCARE, INC Electrocardiogram noise reduction using multi-dimensional filtering
5840040, Dec 18 1992 The Regents of the University of California; Regents of the University of California, The Encephalolexianalyzer
5842986, Jun 25 1996 MEDNOVUS, INC Ferromagnetic foreign body screening method and apparatus
5845639, Aug 10 1990 BOARD OF REGENTS OF THE UNIVERSITY OF WASHINGTON, THE Optical imaging methods
5846189, Sep 08 1989 System for quantifying asynchrony between signals
5846208, Sep 04 1996 Siemens Aktiengesellschaft Method and apparatus for the evaluation of EEG data
5853005, May 02 1996 ARMY, UNITED STATES OF AMERICA, AS REPRESENTED BY THE SECRETARY OF, THE Acoustic monitoring system
5857978, Mar 20 1996 Lockheed Martin Energy Systems, Inc. Epileptic seizure prediction by non-linear methods
5859533, Sep 22 1994 Oyo Corporation Process for the production of a supply current of a solenoid for a measuring probe for electromagnetic tomography
5871517, Jan 15 1997 Somatics, Inc. Convulsive therapy apparatus to stimulate and monitor the extent of therapeutic value of the treatment
5877801, May 13 1991 Sony Corporation System for omnidirectional image viewing at a remote location without the transmission of control signals to select viewing parameters
5884626, Sep 02 1994 National Institute of Advanced Industrial Science and Technology Apparatus and method for analyzing information relating to physical and mental condition
5885976, May 08 1995 Methods useful for the treatment of neurological and mental disorders related to deficient serotonin neurotransmission and impaired pineal melatonin functions
5891131, Feb 01 1993 Arizona Board of Regents Method and apparatus for automated simulation and design of corneal refractive procedures
5899867, Oct 11 1996 System for self-administration of electroencephalographic (EEG) neurofeedback training
5911581, Feb 21 1995 BRAIN COM, INC Interactive computer program for measuring and analyzing mental ability
5916171, May 31 1994 VITAL MEDICAL LTD Tissue monitor
5921245, Jun 03 1996 Method for modification of anti-social behavior
5928272, May 02 1998 LivaNova USA, Inc Automatic activation of a neurostimulator device using a detection algorithm based on cardiac activity
5938598, Mar 18 1996 Director-General of Agency of Industrial Science and Technology Magnetic field source movable phantom head
5938688, Oct 22 1997 Cornell Research Foundation, Inc Deep brain stimulation method
5954662, Feb 17 1995 EP Technologies, Inc. Systems and methods for acquiring endocardially or epicardially paced electrocardiograms
5970499, Apr 11 1997 SURGICAL NAVIGATION TECHNOLOGIES, INC Method and apparatus for producing and accessing composite data
5971923, Dec 31 1997 Siemens Medical Solutions USA, Inc Ultrasound system and method for interfacing with peripherals
5983129, Feb 19 1998 COWAN, JONATHAN DANIEL Method for determining an individual's intensity of focused attention and integrating same into computer program
5995868, Jan 23 1996 University of Kansas System for the prediction, rapid detection, warning, prevention, or control of changes in activity states in the brain of a subject
5999856, Feb 21 1997 St. Croix Medical, Inc. Implantable hearing assistance system with calibration and auditory response testing
6002254, Jan 30 1998 Kabushiki Kaisha Toshiba Method and apparatus for nuclear magnetic resonance imaging of physiological function information
6002952, Apr 14 1997 JPMorgan Chase Bank, National Association Signal processing apparatus and method
6011990, Oct 19 1995 Arthur Schultz Method and device for evaluating an EEG carried out in the context of anaesthesia or intensive care
6011991, Dec 07 1998 Avogadro, Maxwell, Boltzman, LLC Communication system and method including brain wave analysis and/or use of brain activity
6016444, Dec 10 1997 New York University Automatic control of anesthesia using quantitative EEG
6021345, Jun 20 1990 Cedars-Sinai Medical Center Methods for detecting propensity for fibrillation using an electrical restitution curve
6023161, Feb 28 1997 The Regents of the University of California; CALIFORNIA, UNIVERSITY OF, REGENTS OF THE, THE Low-noise SQUID
6026173, Jul 05 1997 EMTensor GmbH Electromagnetic imaging and therapeutic (EMIT) systems
6032072, Jan 30 1998 Covidien LP Method for enhancing and separating biopotential signals
6042548, Nov 14 1997 TRILOBOT, INC Virtual neurological monitor and method
6044292, Sep 21 1998 Apparatus and method for predicting probability of explosive behavior in people
6050940, Jun 17 1996 MEDCOM NETWORK SYSTEMS, LLC General-purpose medical instrumentation
6050962, Apr 21 1997 Immersion Corporation Goniometer-based body-tracking device and method
6052619, Aug 07 1997 New York University Brain function scan system
6053739, Apr 10 1996 Measurement of attention span and attention deficits
6057846, Jul 14 1995 Virtual reality psychophysiological conditioning medium
6066084, Oct 28 1996 Zentralinstitut fur Biomedizinische Technik Universitat Ulm Method and apparatus for focused neuromagnetic stimulation and detection
6067462, Apr 14 1997 JPMorgan Chase Bank, National Association Signal processing apparatus and method
6067467, Feb 07 1994 New York University EEG operative and post-operative patient monitoring method
6069369, Feb 27 1987 Hitachi, Ltd. Superconducting device
6070098, Apr 11 1997 CIRCADIAN TECHNOLOGIES, INC Method of and apparatus for evaluation and mitigation of microsleep events
6071246, Dec 28 1995 Pilot Blankenfelde Medizinisch-Electronische Gerate GmbH Process for automatic determination of hearing acuity, particularly of newborns and infants
6080164, Aug 18 1995 BRIGHAM & WOMEN S HOSPITAL Versatile stereotactic device
6081735, Oct 06 1993 JPMorgan Chase Bank, National Association Signal processing apparatus
6088611, Aug 18 1995 ILLINOIS, UNIVERSITY OF, BOARD OF TRUSTEES, THE Model based method for high resolution dynamic imaging
6092058, Jan 08 1998 The United States of America as represented by the Secretary of the Army Automatic aiding of human cognitive functions with computerized displays
6097980, Dec 24 1998 Quantitative electroencephalographic (QEEG) process and apparatus for assessing attention deficit hyperactivity disorder
6097981, Apr 30 1997 UNIQUE LOGIC & TECHNOLOGY Electroencephalograph based biofeedback system and method
6099319, Feb 24 1998 THE NIELSEN COMPANY US , LLC , A DELAWARE LIMITED LIABILITY COMPANY Neuroimaging as a marketing tool
6104956, May 30 1997 BOARD OF TRUSTEES OF SOUTHERN ILLINOIS UNIVERSITY OF SPRINGFIELD, ILLINOIS Methods of treating traumatic brain injury by vagus nerve stimulation
6115631, Dec 18 1998 Apparatus and method for predicting probability of ruminating behavior in people
6117075, Sep 21 1998 Meduck Ltd. Depth of anesthesia monitor
6129681, Sep 02 1994 National Institute of Advanced Industrial Science and Technology Apparatus and method for analyzing information relating to physical and mental condition
6132724, Apr 29 1998 SYNAPTAMINE, INC Allelic polygene diagnosis of reward deficiency syndrome and treatment
6144872, Apr 30 1999 YNI LIMITED Analyzing events in the thalamus by noninvasive measurements of the cortex of the brain
6149586, Jan 29 1998 System and method for diagnosing executive dysfunctions using virtual reality and computer simulation
6154026, Apr 30 1997 The Regents of the University of California Asymmetric planar gradiometer for rejection of uniform ambient magnetic noise
6155966, Nov 17 1998 Apparatus and method for toning tissue with a focused, coherent electromagnetic field
6155993, Mar 31 1999 QUEEN S UNIVERSITY AT KINGSTON Kinesiological instrument for limb movements
6157850, Mar 07 1991 JPMorgan Chase Bank, National Association Signal processing apparatus
6157857, Jul 24 1998 Apparatus for determining sleep staging
6161031, Aug 10 1990 Board of Regents of the University of Washington Optical imaging methods
6167298, Jan 08 1998 Devices and methods for maintaining an alert state of consciousness through brain wave monitoring
6167311, Jun 14 1999 Electro Core Techniques, LLC Method of treating psychological disorders by brain stimulation within the thalamus
6171239, Aug 17 1998 Emory University Systems, methods, and devices for controlling external devices by signals derived directly from the nervous system
6171258, Oct 08 1998 NOVASOM, INC Multi-channel self-contained apparatus and method for diagnosis of sleep disorders
6182013, Jul 23 1999 Schlumberger Technology Corporation Methods and apparatus for dynamically estimating the location of an oil-water interface in a petroleum reservoir
6188924, Feb 17 1995 Ep Technologies Systems and methods for acquiring making time-sequential measurements of biopotentials sensed in myocardial tissue
6195576, Mar 09 1998 New York University Quantitative magnetoencephalogram system and method
6196972, Nov 11 1998 SPENTECH, INC Doppler ultrasound method and apparatus for monitoring blood flow
6205359, Oct 26 1998 Apparatus and method for adjunct (add-on) therapy of partial complex epilepsy, generalized epilepsy and involuntary movement disorders utilizing an external stimulator
6208902, Oct 26 1998 Apparatus and method for adjunct (add-on) therapy for pain syndromes utilizing an implantable lead and an external stimulator
6224549, Apr 20 1999 CAREFUSION 209, INC Medical signal monitoring and display
6226418, Nov 07 1997 Washington University Rapid convolution based large deformation image matching via landmark and volume imagery
6230037, Mar 07 1997 Hitachi, Ltd. Biomagnetic field measuring method and apparatus
6236872, Mar 07 1991 JPMorgan Chase Bank, National Association Signal processing apparatus
6239145, Jun 27 1997 KYUSHU UNIVERSITY Nitroxyl compounds and drugs and reagents containing the same as the active ingredient
6240308, Dec 23 1988 Tyrone L., Hardy; Medical Instrumentation and Diagnostics Corporation Method and apparatus for archiving and displaying anatomico-physiological data in a normalized whole brain mapping and imaging system
6241686, Oct 30 1998 The United States of America as represented by the Secretary of the Army System and method for predicting human cognitive performance using data from an actigraph
6248126, Jan 12 1998 Johns Hopkins University, The Technique for using heat flow management to treat brain disorders
6259399, Mar 08 1996 SnapTrack, Inc. GPS receivers and garments containing GPS receivers and methods for using these GPS receivers
6263189, Sep 29 1997 Triad National Security, LLC Narrowband high temperature superconducting receiver for low frequency radio waves
6266453, Jul 26 1999 CMSI HOLDINGS CORP ; IMPAC MEDICAL SYSTEMS, INC Automated image fusion/alignment system and method
6269270, Oct 26 1998 Neuro and Cardiac Technologies, LLC Apparatus and method for adjunct (add-on) therapy of Dementia and Alzheimer's disease utilizing an implantable lead and external stimulator
6272370, Aug 07 1998 STEREOTAXIS, INC MR-visible medical device for neurological interventions using nonlinear magnetic stereotaxis and a method imaging
6280393, Dec 02 1999 Regents of the University of California, The Method and apparatus for assessing susceptibility to stroke
6287328, Apr 08 1999 Koninklijke Philips Electronics N V Multivariable artifact assessment
6290638, Apr 27 1995 Electromagnetic method of treatment of epilepsy and apparatus therefor
6292688, Feb 28 1996 Advanced Neurotechnologies, Inc.; ADVANCED NEUROTECHNOLOGIES, INC Method and apparatus for analyzing neurological response to emotion-inducing stimuli
6293904, Feb 26 1998 CARESTREAM HEALTH, INC Management of physiological and psychological state of an individual using images personal image profiler
6294917, Sep 13 1999 ELECTROMAGNETIC INSTRUMENTS, INC ; EMI, INC Electromagnetic induction method and apparatus for the measurement of the electrical resistivity of geologic formations surrounding boreholes cased with a conductive liner
6298259, Oct 16 1998 STEREOTAXIS, INC Combined magnetic resonance imaging and magnetic stereotaxis surgical apparatus and processes
6305943, Jan 29 1999 MedDorna, LLC Respiratory sinus arrhythmia training system
6306077, Feb 26 1998 CARESTREAM HEALTH, INC Management of physiological and psychological state of an individual using images overall system
6309342, Feb 26 1998 CARESTREAM HEALTH, INC Management of physiological and psychological state of an individual using images biometric analyzer
6309361, May 04 1998 Method for improving memory by identifying and using QEEG parameters correlated to specific cognitive functioning
6315736, Jun 09 1999 OMRON HEALTHCARE CO , LTD Anesthetic-depth monitor apparatus
6317627, Nov 02 1999 Masimo Corporation Anesthesia monitoring system based on electroencephalographic signals
6319205, Jul 30 1996 Itamar Medical (C.M.) 1997 Ltd. Method and apparatus for the non-invasive detection of medical conditions by monitoring peripheral arterial tone
6322515, Jul 30 1996 Itamar Medical Method and apparatus for the non-invasive detection of medical conditions by monitoring peripheral arterial tone
6325475, Sep 06 1996 MICROFAB TECHNOLOGIES, INC Devices for presenting airborne materials to the nose
6325761, Sep 11 1998 JPMorgan Chase Bank, National Association Device and method for measuring pulsus paradoxus
6331164, Mar 17 2000 INTERACOUSTICS A S Hearing test apparatus and method having adaptive artifact rejection
6332087, Jul 05 1996 EMTensor GmbH Electromagnetic imaging and therapeutic (EMIT) systems
6338713, Aug 18 1998 Covidien LP System and method for facilitating clinical decision making
6339725, May 31 1996 The Board of Trustees of Southern Illinois University Methods of modulating aspects of brain neural plasticity by vagus nerve stimulation
6341236, Apr 30 1999 FLINT HILLS SCIENTIFIC, L L C Vagal nerve stimulation techniques for treatment of epileptic seizures
6343229, Jun 15 1997 Device for measurement and analysis of brain activity of both cerebral hemispheres in a patient
6354087, May 22 1998 SUMITOMO ELECTRIC INDUSTRIES, LTD Method and apparatus for cooling superconductor
6354299, Oct 27 1997 NEUROPACE, INC , A DELAWARE CORPORATION Implantable device for patient communication
6356079, Dec 14 1998 Kabushiki Kaisha Toshiba Phase-shift type magnetic-field sensor using a magnetic substance
6356781, Mar 31 2000 Lucent Technologies, Inc.; Lucent Technologies, INC Functional magnetic resonance imaging capable of detecting the occurrence of neuronal events with high temporal accuracy
6356788, Oct 26 1998 APPARATUS AND METHOD FOR ADJUNCT (ADD-ON) THERAPY FOR DEPRESSION, MIGRAINE, NEUROPSYCHIATRIC DISORDERS, PARTIAL COMPLEX EPILEPSY, GENERALIZED EPILEPSY AND INVOLUNTARY MOVEMENT DISORDERS UTILIZING AN EXTERNAL STIMULATOR
6358201, Mar 02 1999 QUANTUM INTECH, INC Method and apparatus for facilitating physiological coherence and autonomic balance
6364845, Sep 17 1998 ROCHESTER, UNIVERSITY OF Methods for diagnosing visuospatial disorientation or assessing visuospatial orientation capacity
6366813, Aug 05 1998 DiLorenzo Biomedical, LLC Apparatus and method for closed-loop intracranical stimulation for optimal control of neurological disease
6366814, Oct 26 1998 Neuro and Cardiac Technologies, LLC External stimulator for adjunct (add-on) treatment for neurological, neuropsychiatric, and urological disorders
6370414, Jan 23 1998 VSM MEDTECH SYSTEMS INC System and method for measuring, estimating and displaying RMS current density maps
6370423, Oct 05 1998 Method for analysis of biological voltage signals
6374131, Jul 28 1999 Shimadzu Corporation Biomagnetism measuring method and apparatus
6375614, Jun 17 1996 MEDCOM NETWORK SYSTEMS, LLC General-purpose medical istrumentation
6377833, Jan 25 1999 System and method for computer input of dynamic mental information
6385479, Mar 31 1999 Science & Technology Corporation Method for determining activity in the central nervous system
6385486, Aug 07 1997 New York University Brain function scan system
6390979, Aug 24 2001 Noninvasive transcranial Doppler ultrasound computerized mental performance testing system
6393363, Jun 28 2000 Schlumberger Technology Corporation Method and apparatus for the measurement of the electrical resistivity of geologic formations employing modeling data
6394963, Jun 20 2000 MCLEAN HOSPITAL CORPORATION, THE Technique for diagnosing attention deficit disorder
6402520, Apr 30 1997 Unique Logic and Technology, Inc.; UNIQUE LOGIC AND TECHNOLOGY, INC , A CORP OF NORTH CAROLINA Electroencephalograph based biofeedback system for improving learning skills
6402689, Sep 30 1998 VTQ IP HOLDING CORPORATION Methods, systems, and associated implantable devices for dynamic monitoring of physiological and biological properties of tumors
6408107, Jul 10 1996 Washington University Rapid convolution based large deformation image matching via landmark and volume imagery
6418344, Feb 24 2000 ElectroCore Techniques, LLC Method of treating psychiatric disorders by electrical stimulation within the orbitofrontal cerebral cortex
6419629, Oct 30 1998 The United States of America as represented by the Secretary of the Army Method for predicting human cognitive performance
6427086, Oct 27 1997 NeuroPace, Inc Means and method for the intracranial placement of a neurostimulator
6428490, Apr 21 1997 Immersion Corporation Goniometer-based body-tracking device and method
6430443, Mar 21 2000 Method and apparatus for treating auditory hallucinations
6435878, Feb 27 1997 BCI, LLC; COGNITIVE DIAGNOSTICS, INC ; BRAIN COM, INC ; @BRAIN COM, INC Interactive computer program for measuring and analyzing mental ability
6442421, Apr 27 2000 Centre National de la Recherche Scientifique METHOD FOR THE MEDICAL MONITORING IN REAL TIME OF A PATIENT FROM THE ANALYSIS OF ELECTROENCEPHALOGRAMS TO CHARACTERIZE AND DIFFERENTIATE BETWEEN PHYSIOLOGICAL OR PATHOLOGICAL CONDITIONS, AND A METHOD FOR ANTICIPATING EPILEPTIC SEIZURES
6442948, Dec 25 1998 Japan Science and Technology Corporation Liquid helium recondensation device and transfer line used therefor
6466816, Dec 02 1999 Regents of the University of California, The Method and apparatus for assessing susceptibility to stroke
6470220, Mar 29 1999 Los Alamos National Security, LLC Diagnosis and treatment of cancers using in vivo magnetic domains
6475163, Jan 07 2000 NATUS MEDICAL INC Hearing evaluation device with patient connection evaluation capabilities
6482165, Jun 20 2000 MCLEAN HOSPITAL CORPORATION, THE Homekit for determining attention deficit hyperactivity disorder
6487441, Feb 17 1995 EP Technologies, Inc. Systems and methods for acquiring and analyzing electrograms in myocardial tissue
6488617, Oct 13 2000 Universal Hedonics Method and device for producing a desired brain state
6490472, Sep 03 1999 The MCW Research Foundation, Inc. MRI system and method for producing an index indicative of alzheimer's disease
6493577, Sep 23 1997 Natus Medical Incorporated Method and system for detecting white matter neural injury and predicting neurological outcome particularly for preterm infants
6496724, Dec 31 1998 ADVANCED BRAIN MONITORING, INC Method for the quantification of human alertness
6497658, Dec 17 1999 Alarm upon detection of impending sleep state
6497699, Aug 09 2000 The Research Foundation of State University of New York Hybrid neuroprosthesis for the treatment of brain disorders
6503085, Jan 29 1998 Use of virtual reality and desk top computer formats to diagnose executive dysfunctions
6507754, Apr 27 2000 Centre National de la Recherche Scientifique Device for the medical monitoring in real time of a patient from the analysis of electroencephalograms
6510340, Jan 10 2000 JORDAN NEUROSCIENCE, INC Method and apparatus for electroencephalography
6511424, Apr 11 1997 CIRCADIAN TECHNOLGIES, INC Method of and apparatus for evaluation and mitigation of microsleep events
6516246, Sep 11 2000 Mimicking Man Manually, Inc. Method and system for determining native neurological dominant hemisphere
6520905, Feb 26 1998 CARESTREAM HEALTH, INC Management of physiological and psychological state of an individual using images portable biosensor device
6520921, Jun 20 2000 MCLEAN HOSPITAL CORPORATION, THE Method for determining attention deficit hyperactivity disorder (ADHD) medication dosage and for monitoring the effects of (ADHD) medication
6522906, Dec 08 1998 Intuitive Surgical Operations, Inc Devices and methods for presenting and regulating auxiliary information on an image display of a telesurgical system to assist an operator in performing a surgical procedure
6524249, Nov 11 1998 Spentech, Inc. Doppler ultrasound method and apparatus for monitoring blood flow and detecting emboli
6526297, Oct 04 1999 Instrumentarium Corp Method and apparatus for quantifying the hypnotic component of the depth of anesthesia by monitoring changes in optical scattering properties of brain tissue
6526415, Apr 11 1997 Surgical Navigation Technologies, Inc. Method and apparatus for producing an accessing composite data
6527715, Oct 30 1998 UNITED STATES ARMY System and method for predicting human cognitive performance using data from an actigraph
6527730, Dec 21 2000 MCLEAN HOSPITAL CORPORATION, THE Reducing noise in a technique for diagnosing attention deficit hyperactivity disorder
6529759, Mar 08 2001 Magstim Group, Incorporated Method for mapping internal body tissue
6529773, Aug 01 2001 The United States of America as represented by the Secretary of the Air Force Communication and control by means of brainwave and other processes causing voltage changes that can be measured from the body
6530884, Oct 30 1998 UNITED STATES ARMY Method and system for predicting human cognitive performance
6534986, May 01 2000 Schlumberger Technology Corporation Permanently emplaced electromagnetic system and method for measuring formation resistivity adjacent to and between wells
6538436, Aug 28 1998 Megin Oy Method and apparatus for eliminating background interference signals from multichannel signal measurements
6539245, Mar 07 1997 Hitachi, Ltd. Biomagnetic field measuring method and apparatus
6539263, Jun 11 1999 Cornell Research Foundation, Inc Feedback mechanism for deep brain stimulation
6544170, Jun 21 1999 Shimadzu Corporation; Riken Biosignal measuring method and apparatus
6546378, Apr 24 1997 BRIGHT IDEAS L L C , A LIMITED LIABILITY COMPANY OF UTAH Signal interpretation engine
6547736, Nov 11 1998 Spentech, Inc. Doppler ultrasound method and apparatus for monitoring blood flow and detecting emboli
6547746, Aug 27 2001 Board of Supervisors of Louisiana State University and Agricultural and Mechanical College Method and apparatus for determining response thresholds
6549804, Jan 23 1996 University of Kansas System for the prediction, rapid detection, warning, prevention or control of changes in activity states in the brain of a subject
6551243, Jan 24 2001 Siemens Medical Solutions USA, Inc System and user interface for use in providing medical information and health care delivery support
6553252, Oct 30 1998 The United States of America as represented by the Secretary of the Army Method and system for predicting human cognitive performance
6556695, Feb 05 1999 Mayo Foundation for Medical Education and Research Method for producing high resolution real-time images, of structure and function during medical procedures
6556861, Nov 20 2000 New York University Fetal brain monitor
6556868, May 31 1996 The Board of Trustees of Southern Illinois University Methods for improving learning or memory by vagus nerve stimulation
6557558, Aug 31 1999 Hitachi, LTD Medical treatment apparatus
6560486, Oct 12 1999 FLINT HILLS SCIENTIFIC, L L C Bi-directional cerebral interface system
6565518, May 25 2001 MCLEAN HOSPITAL CORPORATION, THE Technique for diagnosing attention deficit hyperactivity disorder
6574573, Oct 27 1998 Gram Corporation Spectrum analysis and display method time series
6587727, Apr 30 1999 Vagal nerve stimulation techniques for treatment of epileptic seizures
6587729, Dec 13 1996 The United States of America as represented by the Secretary of the Air Force Apparatus for audibly communicating speech using the radio frequency hearing effect
6591132, Nov 30 2001 Natus Medical Incorporated Artifact detection in encephalogram data using an event model
6591137, Nov 09 2000 NeuroPace, Inc Implantable neuromuscular stimulator for the treatment of gastrointestinal disorders
6594524, Dec 12 2000 TRUSTEES OF THE UNIVERSITY OF PENNSYLVANIA, THE Adaptive method and apparatus for forecasting and controlling neurological disturbances under a multi-level control
6597954, Oct 27 1997 NEUROSPACE, INC ; NeuroPace, Inc System and method for controlling epileptic seizures with spatially separated detection and stimulation electrodes
6602202, May 19 2000 Baycrest Centre for Geriatric Care System and methods for objective evaluation of hearing using auditory steady-state responses
6603502, May 13 1991 Sony Corporation System for omnidirectional image viewing at a remote location without the transmission of control signals to select viewing parameters
6609030, Feb 24 2000 ElectroCore Techniques, LLC; ELECTROCARE TECHNIQUES, LLC Method of treating psychiatric diseases by neuromodulation within the dorsomedial thalamus
6611698, Oct 13 1998 Hitachi, LTD; HITACHI HEALTHCARE MANUFACTURING, LTD Optical measuring instrument
6615158, Jun 25 2001 National Instruments Corporation System and method for analyzing a surface by mapping sample points onto the surface and sampling the surface at the mapped points
6616611, Nov 11 1998 Spentech, Inc. Doppler ultrasound method and apparatus for monitoring blood flow
6622036, Feb 09 2000 MYND ANALYTICS, INC , A CALIFORNIA CORPORATION Method for classifying and treating physiologic brain imbalances using quantitative EEG
6622047, Jul 28 2001 LivaNova USA, Inc Treatment of neuropsychiatric disorders by near-diaphragmatic nerve stimulation
6625485, Dec 31 1998 Advanced Brain Monitoring, Inc. Method for the quantification of human alertness
6626676, Apr 30 1997 Unique Logic and Technology, Inc. Electroencephalograph based biofeedback system for improving learning skills
6633686, Nov 05 1998 Washington University Method and apparatus for image registration using large deformation diffeomorphisms on a sphere
6644976, Sep 10 2001 BRIGHTSTAR LEARNING LTD Apparatus, method and computer program product to produce or direct movements in synergic timed correlation with physiological activity
6648822, Jul 24 2000 Sharp Kabushiki Kaisha Communication apparatus and communication method for outputting an estimate of a patient's mental state
6648880, Feb 16 2001 Medtronic Cryocath LP Method of using cryotreatment to treat brain tissue
6650917, Mar 07 1991 JPMorgan Chase Bank, National Association Signal processing apparatus
6652458, Jun 20 2000 MCLEAN HOSPITAL CORPORATION, THE ADHD detection by eye saccades
6652470, Jun 20 2000 MCLEAN HOSPITAL CORPORATION, THE Using image modification and temperature biofeedback to diagnose and treat ADHD
6654632, Jul 06 2000 Algodyne, Ltd. System for processing a subject's electrical activity measurements
6654729, Sep 27 1999 Leidos, Inc Neuroelectric computational devices and networks
6656137, Nov 29 1995 Omega Assembly Trust Vestibular and RAS enhancing device
6658287, Aug 24 1998 Georgia Tech Research Corporation Method and apparatus for predicting the onset of seizures based on features derived from signals indicative of brain activity
6663571, May 28 2002 Transcranial doppler ultrasound device for odor evaluation
6665552, Feb 21 2001 Hitachi, LTD Gradiometer integrating pickup coils and magnetic field measurement system
6665553, Apr 27 2001 Hitachi, Ltd. Biomagnetic field measuring apparatus using squid magnetometers for evaluating a rotational property of a current in a subject
6665562, Dec 07 1999 George Mason University Adaptive electric field modulation of neural systems
6671555, Apr 27 2001 Medtronic, Inc Closed loop neuromodulation for suppression of epileptic activity
6671556, Apr 30 1999 Vagal nerve stimulation techniques for treatment of epileptic seizures
6678548, Oct 20 2000 The Trustees of the University of Pennsylvania Unified probabilistic framework for predicting and detecting seizure onsets in the brain and multitherapeutic device
6684098, Aug 16 1996 BRIGHAM & WOMEN S HOSPITAL, INC Versatile stereotactic device and methods of use
6684105, Aug 31 2001 Medtronic, Inc Treatment of disorders by unidirectional nerve stimulation
6687525, Jun 07 2000 New York University Method and system for diagnosing and treating thalamocortical dysrhythmia
6695761, Jan 30 2002 ELECTROHEALING HOLDINGS, INC Apparatus for assisting a heart
6697660, Jan 23 1998 VSM MEDTECH SYSTEMS INC Method for functional brain imaging from magnetoencephalographic data by estimation of source signal-to-noise ratio
6699194, Apr 14 1997 JPMorgan Chase Bank, National Association Signal processing apparatus and method
6701173, Feb 27 1996 Kent Ridge Digital Labs Curved surgical instruments and method of mapping a curved path for stereotactic surgery
6703838, Apr 13 1998 Schlumberger Technology Corporation Method and apparatus for measuring characteristics of geological formations
6708051, Nov 10 1998 Compumedics Limited FMRI compatible electrode and electrode placement techniques
6708064, Feb 24 2000 Modulation of the brain to affect psychiatric disorders
6708184, Apr 11 1997 Medtronic Surgical Navigation Technologies Method and apparatus for producing and accessing composite data using a device having a distributed communication controller interface
6709399, Oct 20 2000 Cardiotran LCC; Premier Hear LLC Method and system for the detection of heart disease
6725080, Mar 01 2000 SURGICAL NAVIGATION TECHNOLOGIES, INC Multiple cannula image guided tool for image guided procedures
6726624, Mar 06 2002 MCLEAN HOSPITAL CORPORATION, THE METHOD AND APPARATUS FOR DETERMINING ATTENTION DEFICIT HYPERACTIVITY DISORDER (ADHD) MEDICATION DOSAGE AND FOR MONITORING THE EFFECTS OF ADHD MEDICATION ON PEOPLE WHO HAVE ADHD USING COMPLEMENTARY TESTS
6728424, Sep 15 2000 Koninklijke Philips Electronics, N.V. Imaging registration system and method using likelihood maximization
6728564, Jul 03 2001 Instrumentarium Corp Configurable sensor system for measuring biopotentials
6731975, Oct 16 2000 Instrumentarium Corp Method and apparatus for determining the cerebral state of a patient with fast response
6735460, Mar 07 1997 Hitachi, Ltd. Biomagnetic field measuring method and apparatus
6735467, Apr 15 2002 Persyst Development Corporation Method and system for detecting seizures using electroencephalograms
6735475, Jan 30 2001 Boston Scientific Neuromodulation Corporation Fully implantable miniature neurostimulator for stimulation as a therapy for headache and/or facial pain
6740032, Oct 30 1998 Method and system for predicting human congnitive performance
6743167, Oct 30 1998 The United States of America as represented by the Secretary of the Army Method and system for predicting human cognitive performance using data from an actigraph
6743182, May 25 2001 MCLEAN HOSPITAL CORPORATION, THE Method for determining attention deficit hyperactivity disorder (ADHD) medication dosage and for monitoring the effects of (ADHD) medication
6745060, Mar 07 1991 JPMorgan Chase Bank, National Association Signal processing apparatus
6745156, Apr 24 1997 Bright Ideas, L.L.C. Petroleum exploration and prediction apparatus and method
6746409, Feb 14 2002 MCLEAN HOSPITAL CORPORATION, THE Technique for diagnosing attention deficit hyperactivity disorder using complimentary tests
6751499, Jul 06 2000 Algodyne, Ltd. Physiological monitor including an objective pain measurement
6758813, Jul 25 2002 Method to universally connect applications data streams to VRML content
6768920, Jul 06 2000 Algodyne, Ltd. System for delivering pain-reduction medication
6773400, Apr 01 2002 Noninvasive transcranial doppler ultrasound face and object recognition testing system
6774929, Nov 03 2000 Avotec Inc.; AVOTEC, A FLORIDA CORPORATION Shielded video projection system for MRI
6775405, Sep 29 2000 DOWA MINING COMPANY, LIMITED Image registration system and method using cross-entropy optimization
6782292, Jun 20 2000 Boston Scientific Neuromodulation Corporation System and method for treatment of mood and/or anxiety disorders by electrical brain stimulation and/or drug infusion
6785409, Oct 24 2000 Koninklijke Philips Electronics, N.V. Segmentation method and apparatus for medical images using diffusion propagation, pixel classification, and mathematical morphology
6788975, Jan 30 2001 Boston Scientific Neuromodulation Corporation Fully implantable miniature neurostimulator for stimulation as a therapy for epilepsy
6791331, Apr 13 1998 Schlumberger Technology Corporation Method and apparatus for measuring characteristics of geological formations
6795724, Feb 19 2002 Color-based neurofeedback
6798898, Feb 26 1998 CARESTREAM HEALTH, INC Management of physiological and psychological state of an individual using images therapeutic imaging classification system
6801648, Aug 04 2000 VIOPTIX, INC Optical imaging system with symmetric optical probe
6801803, Oct 16 2000 Instrumentarium Corp Method and apparatus for determining the cerebral state of a patient with fast response
6804558, Jul 07 1999 ROSELLINI SCIENTIFIC BENELUX, SPRI System and method of communicating between an implantable medical device and a remote computer system or health care provider
6804661, Apr 24 1997 Bright Ideas, L.L.C.; BRIGHT IDEAS, LLC Drug profiling apparatus and method
6815949, Jul 19 2001 Hitachi, Ltd. Apparatus for measuring a magnetic field
6816744, May 29 2001 Reproductive Health Technologies, Inc.; REPRODUCTIVE HEALTH TECHNOLOGIES, INC DEVICE AND SYSTEM FOR REMOTE FOR IN-CLINIC TRANS-ABDOMINAL/VAGINAL/CERVICAL ACQUISITION, AND DETECTION, ANALYSIS, AND COMMUNICATION OF MATERNAL UTERINE AND MATERNAL AND FETAL CARDIAC AND FETAL BRAIN ACTIVITY FROM ELECTRICAL SIGNALS
6819956, Aug 05 1998 DiLorenzo Biomedical, LLC Optimal method and apparatus for neural modulation for the treatment of neurological disease, particularly movement disorders
6826426, Jul 06 2000 Algodyne, Ltd. Objective pain signal acquisition system and processed signal
6843774, May 25 2001 MCLEAN HOSPITAL CORPORATION, THE Technique for diagnosing attention deficit hyperactivity disorder
6853186, Jan 15 2002 National University of Singapore; SINGAPORE, NATIONAL UNIVERSITY OF Variable permeability magnetic field sensor and method
6856830, Jul 19 2001 Method and apparatus of three dimension electrocardiographic imaging
6863127, Mar 27 2000 Schlumberger Technology Corporation System and method for making an opening in a subsurface tubular for reservoir monitoring
6865494, Dec 03 2001 INVIVO CORPORATION Method and apparatus for noise tomography
6873872, Dec 07 1999 George Mason University Adaptive electric field modulation of neural systems
6875174, Jun 17 1996 MEDCOM NETWORK SYSTEMS, LLC General-purpose medical instrumentation
6876196, Mar 19 2001 Megin Oy Determining a position of objects in a predetermined coordinate system
6879859, Oct 26 1998 Neuro and Cardiac Technologies, LLC External pulse generator for adjunct (add-on) treatment of obesity, eating disorders, neurological, neuropsychiatric, and urological disorders
6882881, Oct 19 1999 Johns Hopkins University, The Techniques using heat flow management, stimulation, and signal analysis to treat medical disorders
6885192, Feb 06 2002 Regents of the University of California, The SQUID detected NMR and MRI at ultralow fields
6885886, Sep 11 2000 Brainlab AG Method and system for visualizing a body volume and computer program product
6886964, Jun 26 2001 PHOTOMED TECHNOLOGIES, INC Illuminator with filter array and bandwidth controller
6893407, May 05 2000 PERMOTION LLC Communication method and apparatus
6896655, Aug 05 2002 CARESTREAM HEALTH, INC System and method for conditioning the psychological state of a subject using an adaptive autostereoscopic display
6907280, Dec 02 1999 General Hospital Corporation, The Method and apparatus for objectively measuring pain, pain treatment and other related techniques
6915241, Apr 20 2001 Fraunhofer-Gesellschaft zur Foerderung der Angewandten Forschung E V Method for segmentation and identification of nonstationary time series
6920357, Apr 30 1999 Vagal nerve stimulation techniques for treatment of epileptic seizures
6926921, May 05 2003 SAMSUNG ELECTRONICS CO , LTD Imprint lithography for superconductor devices
6928354, Dec 12 2002 Electronics and Telecommunications Research Institute Apparatus and method for controlling vehicle brake using brain waves
6931274, Sep 23 1997 Natus Medical Incorporated Processing EEG signals to predict brain damage
6931275, Jun 07 2002 System for reduction of undesirable brain wave patterns using selective photic stimulation
6936012, Jun 18 2001 NeuroMetrix, Inc.; NEUROMETRIX, INC Method and apparatus for identifying constituent signal components from a plurality of evoked physiological composite signals
6947790, Jun 26 2000 Sam Technology, Inc. Neurocognitive function EEG measurement method and system
6950697, Jan 10 2000 Jordan Neuroscience, Inc. Electroencephalogram acquisition unit and system
6950698, Jul 02 2003 Instrumentarium Corp Method of positioning electrodes for central nervous system monitoring
6959215, Dec 09 2002 ADVANCED NEUROMODULATION SYSTEMS, INC Methods for treating essential tremor
6961618, Apr 30 1999 Flint Hills Scientific, L.L.C. Vagal nerve stimulation techniques for treatment of epileptic seizures
6963770, Sep 30 1998 VTQ IP HOLDING CORPORATION Methods, systems, and associated implantable devices for dynamic monitoring of physiological and biological properties of tumors
6963771, Sep 30 1998 VTQ IP HOLDING CORPORATION Methods, systems, and associated implantable devices for radiation dose verification for therapies used to treat tumors
6978179, Feb 27 2002 Method and apparatus for magnetic brain wave stimulation
6980863, Mar 20 2003 Medtronic, Inc. Neurological stimulation lead extension
6981947, Jan 22 2002 UNIVERSITY OF FLORIDA RESEARCH FOUNDATION, INC Method and apparatus for monitoring respiratory gases during anesthesia
6983184, May 13 2002 PRICE, GREGORY W DR Interactive-modified interactive event related potential (IMIERP)
6983264, Nov 01 2000 International Business Machines Corporation Signal separation method and apparatus for restoring original signal from observed data
6985769, Feb 13 2001 Jordan Neuroscience, Inc. Automated realtime interpretation of brain waves
6988056, Apr 24 1997 Bright Ideas, L.L.C. Signal interpretation engine
6990377, Apr 24 2003 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for facilitating and/or effectuating development, rehabilitation, restoration, and/or recovery of visual function through neural stimulation
6993380, Jun 04 2003 Cleveland Medical Devices, Inc. Quantitative sleep analysis method and system
6996261, Jan 30 2001 Methods for physiological monitoring, training, exercise and regulation
6996549, May 01 1998 Health Discovery Corporation Computer-aided image analysis
7003352, May 24 2002 Boston Scientific Neuromodulation Corporation Treatment of epilepsy by brain stimulation
7006872, Apr 27 2001 Medtronic, Inc. Closed loop neuromodulation for suppression of epileptic activity
7010340, Sep 30 1998 VTQ IP HOLDING CORPORATION Methods, systems, and associated implantable devices for dynamic monitoring of physiological and biological properties of tumors
7010351, Jul 31 2000 ADVANCED NEUROMODULATION SYSTEMS, INC Methods and apparatus for effectuating a lasting change in a neural-function of a patient
7011410, Nov 22 2000 BRAINSTEM BIOMETRICS Method and apparatus for monitoring eye tremor
7011814, Apr 23 2001 VTQ IP HOLDING CORPORATION Systems, methods and devices for in vivo monitoring of a localized response via a radiolabeled analyte in a subject
7014613, May 19 2000 System and method for objective evaluation of hearing using auditory steady-state responses
7016722, Nov 20 2000 New York University System and method for fetal brain monitoring
7022083, Oct 22 2002 Hitachi, Ltd.; Hitachi Medical Corporation Measurement system for living bodies
7023206, Oct 18 2002 Virginia Tech Intellectual Properties, Inc Magnetoelectric magnetic field sensor with longitudinally biased magnetostrictive layer
7024247, Oct 15 2001 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for reducing the likelihood of inducing collateral neural activity during neural stimulation threshold test procedures
7030617, Apr 13 1998 Schlumberger Technology Corporation System, apparatus, and method for conducting electromagnetic induction surveys
7035686, Feb 19 2002 Color-based neurofeedback
7037260, Mar 06 2002 McLean Hospital Corporation Method and apparatus for determining attention deficit hyperactivity disorder (ADHD) medication dosage and for monitoring the effects of ADHD medication on people who have ADHD using complementary tests
7038450, Oct 16 2002 Trustees of Princeton University; Washington, University of High sensitivity atomic magnetometer and methods for using same
7039266, Sep 03 2004 MIND INSTITUTE, THE Nonmetallic input device for magnetic imaging and other magnetic field applications
7039547, Mar 12 2004 VSM MEDTECH SYSTEMS INC Method and apparatus for localizing biomagnetic signals
7043293, Dec 24 2002 FUJIFILM SONOSITE, INC Method and apparatus for waveform assessment
7053610, Feb 06 2002 The Regents of th University of California Squid detected NMR and MRI at ultralow fields
7054454, Mar 29 2002 BRAINSCOPE SPV LLC Fast wavelet estimation of weak bio-signals using novel algorithms for generating multiple additional data frames
7062391, Mar 12 2004 VSM MEDTECH SYSTEMS INC Motion compensation in biomagnetic measurement
7063535, Dec 21 2001 CARRINGTON BRAIN RESEARCH INSTITUTE, L L C System and method for facilitating early childhood brain development
7070571, Apr 21 1997 Immersion Corporation Goniometer-based body-tracking device
7079977, Oct 15 2002 Medtronic, Inc Synchronization and calibration of clocks for a medical device and calibrated clock
7089927, Oct 23 2002 New York University System and method for guidance of anesthesia, analgesia and amnesia
7092748, Feb 18 2000 Centro Nacional de Investigaciones Cientificas (CNIC) System and method for the tomography of the primary electric current of the brain and of the heart
7099714, Mar 31 2003 Medtronic, Inc Biomedical signal denoising techniques
7104947, Nov 17 2003 NEURONETICS, INC Determining stimulation levels for transcranial magnetic stimulation
7104963, Jan 22 2002 UNIVERSITY OF FLORIDA RESEARCH FOUNDATION INC Method and apparatus for monitoring intravenous (IV) drug concentration using exhaled breath
7105824, May 09 2002 Neurophysics Corporation High resolution photon emission computed tomographic imaging tool
7107090, Dec 08 1998 Intuitive Surgical Operations, Inc Devices and methods for presenting and regulating auxiliary information on an image display of a telesurgical system to assist an operator in performing a surgical procedure
7116102, Feb 06 2002 The Regents of the University of California SQUID detected NMR and MRI at ultralow fields
7117026, Jun 12 2002 Koninklijke Philips Electronics N.V. Physiological model based non-rigid image registration
7119553, Jun 11 2003 KONSULTEUROPE LIMITED JOINT STOCK COMPANY UNITED KINGDOM Security scanners with capacitance and magnetic sensor arrays
7120486, Dec 12 2003 Washington University Brain computer interface
7123955, Oct 29 1999 Tsinghua University Control method and system and the sense organs test method and system based on electrical steady state induced response
7127100, Jun 25 2001 National Instruments Corporation System and method for analyzing an image
7128713, Jul 10 2003 SPENTECH, INC Doppler ultrasound method and apparatus for monitoring blood flow and hemodynamics
7130673, Apr 08 2003 Instrumentarium Corp Method of positioning electrodes for central nervous system monitoring and sensing pain reactions of a patient
7130675, Jun 28 2002 TRISTAN TECHNOLOGIES, INC High-resolution magnetoencephalography system and method
7130691, Jun 27 2002 Method for eradicating pain of central origin resulting from spinal cord injury
7145333, Oct 16 2002 The Trustees of Princeton University; University of Washington High sensitivity atomic magnetometer and methods for using same
7146211, Oct 15 2002 Medtronic, Inc Signal quality monitoring and control for a medical device system
7146217, Jul 13 2000 ADVANCED NEUROMODULATION SYSTEMS, INC Methods and apparatus for effectuating a change in a neural-function of a patient
7146218, Dec 12 2000 The Trustees of the University of Pennsylvania Adaptive method and apparatus for forecasting and controlling neurological disturbances under a multi-level control
7149572, Oct 15 2002 Medtronic, Inc Phase shifting of neurological signals in a medical device system
7149773, Jul 07 1999 BELLTOWER ASSOCIATES LLC System and method of automated invoicing for communications between an implantable medical device and a remote computer system or health care provider
7150710, Jun 26 2001 ALPHA GOLF, INC ; PHOTOMED TECHNOLOGIES, INC Therapeutic methods using electromagnetic radiation
7150715, Feb 05 2001 Network enabled biofeedback administration
7150717, Feb 17 2003 Hitachi, Ltd. Optical measurement apparatus for a living body
7150718, Oct 14 2003 SANYO ELECTRIC CO , LTD Sleep state estimation device and program product for providing a computer with a sleep state estimation function
7151961, May 24 2002 Boston Scientific Neuromodulation Corporation Treatment of movement disorders by brain stimulation
7155279, Mar 28 2003 MEDTRONIC MINIMED, INC Treatment of movement disorders with drug therapy
7163512, Mar 01 2000 QUANTUM INTECH, INC Method and apparatus for facilitating physiological coherence and autonomic balance
7164941, Jan 06 2004 Method and system for contactless monitoring and evaluation of sleep states of a user
7167751, Mar 01 2001 Boston Scientific Neuromodulation Corporation Method of using a fully implantable miniature neurostimulator for vagus nerve stimulation
7170294, Jan 19 2005 KSN Energies, LLC Subsurface imagery for temperature measurement and fluid flow for oil recovery using electromagnetic impedance tomography (EMIT)
7171252, Sep 30 1998 VTQ IP HOLDING CORPORATION Methods, computer program products, and devices for calibrating chronically tissue implanted sensors using chronically tissue
7171339, Jul 12 2000 Cornell Research Foundation, Inc Method and system for analyzing multi-variate data using canonical decomposition
7174206, Oct 15 2002 Medtronic, Inc Signal quality monitoring and control for a medical device system
7176680, May 11 1999 Gravitec Instruments Limited Measurement of magnetic fields using a string fixed at both ends
7177675, Jul 11 2001 MYND ANALYTICS, INC , A CALIFORNIA CORPORATION Electroencephalography based systems and methods for selecting therapies and predicting outcomes
7177678, Oct 12 1999 Bi-directional cerebral interface system
7181505, Jul 07 1999 BELLTOWER ASSOCIATES LLC System and method for remote programming of an implantable medical device
7183381, Oct 26 2004 Agennix Incorporated Composition of lactoferrin related peptides and uses thereof
7184837, Sep 15 2003 Medtronic, Inc. Selection of neurostimulator parameter configurations using bayesian networks
7186209, Oct 09 2003 JACOBSON RESONANCE ENTERPRISES, INC Cardioelectromagnetic treatment
7187169, Nov 03 2004 Regents of the University of California, The NMR and MRI apparatus and method
7190826, Sep 16 2003 Magstim Group, Incorporated Measuring the location of objects arranged on a surface, using multi-camera photogrammetry
7190995, Jun 13 2003 The Regents of the University of Michigan; Altarum Institute; REGENTS OF THE UNIVERSITY OF MICHIGAN, THE System and method for analysis of respiratory cycle-related EEG changes in sleep-disordered breathing
7193413, Jun 23 2003 HITACHI HIGH-TECH CORPORATION Magnetic field measurement apparatus
7196514, Jan 15 2002 SINGAPORE, NATIONAL UNIVERSITY OF Multi-conductive ferromagnetic core, variable permeability field sensor and method
7197352, Aug 26 2002 TRISTAN TECHNOLOGIES, INC High-resolution magnetoencephalography system, components and method
7199708, Jun 30 2003 Sony Corporation Communication apparatus and communication method
7203548, Jun 20 2002 Boston Scientific Neuromodulation Corporation Cavernous nerve stimulation via unidirectional propagation of action potentials
7207948, Jun 24 2004 adidas AG Systems and methods for monitoring cough
7209787, Aug 05 1998 DiLorenzo Biomedical, LLC Apparatus and method for closed-loop intracranial stimulation for optimal control of neurological disease
7209788, Oct 29 2001 Duke University Closed loop brain machine interface
7212851, Oct 24 2002 Massachusetts Institute of Technology Microstructured arrays for cortex interaction and related methods of manufacture and use
7215986, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
7215994, Feb 17 2004 Instrumentarium Corporation Monitoring the neurological state of a patient
7218104, Mar 27 2006 The Regents of the University of California Squid detected NMR and MRI at ultralow fields
7221981, Mar 28 2002 ADVANCED NEUROMODULATION SYSTEMS, INC Electrode geometries for efficient neural stimulation
7222964, Nov 22 2000 Carl Zeiss Meditec AG Method and arrangement for optically stimulating the visual system
7224282, Jun 30 2003 Sony Corporation Control apparatus and method for controlling an environment based on bio-information and environment information
7225013, May 15 2003 WIDEMED TECHNOLOGIES LTD Adaptive prediction of changes of physiological/pathological states using processing of biomedical signals
7228167, Apr 10 2003 Mayo Foundation for Medical Education Method and apparatus for detecting vagus nerve stimulation
7228169, Oct 16 2000 GE Healthcare Finland Oy Method and apparatus for determining the cerebral state of a patient with fast response
7228171, Oct 19 1999 The Johns Hopkins University Signal analysis, heat flow management, and stimulation techniques to treat medical disorders
7228178, Nov 22 2002 MEAGAN MEDICAL, INC Surface stimulation for tremor control
7231245, Jan 04 2002 Covidien LP System and method of assessment of neurological conditions using EEG
7231254, Aug 05 1998 DiLorenzo Biomedical, LLC Closed-loop feedback-driven neuromodulation
7236830, Dec 10 2002 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for enhancing or optimizing neural stimulation therapy for treating symptoms of Parkinson's disease and/or other movement disorders
7236831, Jul 31 2000 ADVANCED NEUROMODULATION SYSTEMS, INC Methods and apparatus for effectuating a lasting change in a neural-function of a patient
7239731, Nov 26 2002 EMTensor GmbH System and method for non-destructive functional imaging and mapping of electrical excitation of biological tissues using electromagnetic field tomography and spectroscopy
7239926, Sep 15 2003 Medtronic, Inc. Selection of neurostimulator parameter configurations using genetic algorithms
7242983, Oct 15 2002 Medtronic, Inc Channel-selective blanking for a medical device system
7242984, Aug 05 1998 DiLorenzo Biomedical, LLC Apparatus and method for closed-loop intracranial stimulation for optimal control of neurological disease
7252090, Sep 15 2003 Medtronic, Inc. Selection of neurostimulator parameter configurations using neural network
7254433, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
7254439, Jan 06 2004 Monebo Technologies, Inc. Method and system for contactless evaluation of fatigue of an operator
7254500, Mar 31 2003 The Salk Institute for Biological Studies Monitoring and representing complex signals
7257439, Aug 21 2002 New York University Brain-machine interface systems and methods
7258659, Jul 25 2002 Electronic device for strengthening the immune system
7260430, Dec 10 2004 National Chiao Tung University Architecture of an embedded internet robot system controlled by brain waves
7267644, Nov 25 2002 FRALEX THERAPEUTICS INC Portable electrotherapy device
7267652, Apr 10 2003 adidas AG Systems and methods for respiratory event detection
7269455, Feb 26 2003 Method and system for predicting and preventing seizures
7269456, May 30 2002 Repetitive visual stimulation to EEG neurofeedback protocols
7269516, May 15 2001 Carnegie Mellon University Systems and methods for monitoring behavior informatics
7276916, Sep 10 2002 HAMMERTECH AS Method and arrangement for measuring conductive component content of a multiphase fluid flow and uses thereof
7277758, Aug 05 1998 DiLorenzo Biomedical, LLC Methods and systems for predicting future symptomatology in a patient suffering from a neurological or psychiatric disorder
7278966, Jan 31 2004 Nokia Technologies Oy System, method and computer program product for managing physiological information relating to a terminal user
7280861, Jun 08 2000 FRALEX THERAPEUTICS, INC Diagnosis and classification of disease and disability using low frequency magnetic field designed pulses (Cnps)
7280867, Oct 15 2002 Medtronic, Inc Clustering of recorded patient neurological activity to determine length of a neurological event
7280870, Jun 04 2002 Brown University Research Foundation Optically-connected implants and related systems and methods of use
7282030, Oct 15 2002 Medtronic, Inc Timed delay for redelivery of treatment therapy for a medical device system
7283861, Apr 30 2002 Brainsonix Corporation Methods for modifying electrical currents in neuronal circuits
7286871, Aug 15 2000 The Regents of the University of California Method and apparatus for reducing contamination of an electrical signal
7288066, Nov 01 2004 Medtronic, Inc Data compression method for implantable medical devices
7292890, Jun 20 2002 Boston Scientific Neuromodulation Corporation Vagus nerve stimulation via unidirectional propagation of action potentials
7295019, Jun 11 2003 Konsulteurope Limited Limited Liability Joint Stock Company United Kingdon Security scanners with capacitance and magnetic sensor arrays
7297110, Aug 27 2004 Systems and methods for remote monitoring of fear and distress responses
7299088, Jun 02 2002 Apparatus and methods for brain rhythm analysis
7299096, Mar 08 2001 ADVANCED NEUROMODULATION SYSTEMS, INC System and method for treating Parkinson's Disease and other movement disorders
7302298, Nov 27 2002 ADVANCED NEUROMODULATION SYSTEMS, INC Methods and systems employing intracranial electrodes for neurostimulation and/or electroencephalography
7305268, Jul 13 2000 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for automatically optimizing stimulus parameters and electrode configurations for neuro-stimulators
7309315, Sep 06 2002 BRIGHTSTAR LEARNING LTD Apparatus, method and computer program product to facilitate ordinary visual perception via an early perceptual-motor extraction of relational information from a light stimuli array to trigger an overall visual-sensory motor integration in a subject
7313442, Apr 30 2004 Advanced Neuromodulation Systems, Inc. Method of treating mood disorders and/or anxiety disorders by brain stimulation
7321837, Oct 15 2002 Medtronic, Inc. Synchronization and calibration of clocks for a medical device and calibrated clock
7324845, May 17 2004 Beth Israel Deaconess Medical Center Assessment of sleep quality and sleep disordered breathing based on cardiopulmonary coupling
7324851, Aug 05 1998 DiLorenzo Biomedical, LLC Closed-loop feedback-driven neuromodulation
7328053, Oct 06 1993 JPMorgan Chase Bank, National Association Signal processing apparatus
7330032, Dec 30 2003 The MITRE Corporation Techniques for building-scale electrostatic tomography
7333619, Mar 29 2002 BRAINSCOPE SPV LLC Fast wavelet estimation of weak bio-signals using novel algorithms for generating multiple additional data frames
7333851, Oct 20 2000 The Trustees of the University of Pennsylvania Unified probabilistic framework for predicting and detecting seizure onsets in the brain and multitherapeutic device
7334892, Dec 03 2004 GEARBOX, LLC Method and system for vision enhancement
7338171, Oct 27 2003 Method and apparatus for visual drive control
7338455, Sep 25 2001 QUEENSLAND, UNIVERSITY OF, THE; UNIVERSITY OF FLORIDA RESEARCH FOUNDATION, INC Method and apparatus for diagnosing schizophrenia and schizophrenia subtype
7340125, Sep 03 2004 MIND INSTITUTE, THE Optical switches and switching methods
7340289, Aug 07 2002 HITACHI HIGH-TECH CORPORATION Biomagnetic field measuring apparatus
7343198, Aug 23 2004 Board of Regents, The University of Texas System System, software, and method for detection of sleep-disordered breathing using an electrocardiogram
7346382, Jul 07 2004 CLEVELAND CLINIC FOUNDATION, THE Brain stimulation models, systems, devices, and methods
7346395, Jun 19 2003 ADVANCED NEUROMODULATION SYSTEMS, INC Method of treating depression, mood disorders and anxiety disorders using neuromodulation
7353064, Dec 10 2002 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for enhancing or optimizing neural stimulation therapy for treating symptoms of movement disorders and/or other neurologic dysfunction
7353065, Sep 14 2004 NeuroPace, Inc Responsive therapy for psychiatric disorders
7355597, May 06 2002 Brown University Research Foundation Method, apparatus and computer program product for the interactive rendering of multivalued volume data with layered complementary values
7359837, Apr 27 2006 Medtronic, Inc. Peak data retention of signal data in an implantable medical device
7363164, Dec 20 2004 Schlumberger Technology Corporation Method of evaluating fluid saturation characteristics in a geological formation
7366571, Dec 10 2004 LivaNova USA, Inc Neurostimulator with activation based on changes in body temperature
7367807, Sep 04 2002 Method for improving word processing skills using visual flash stimuli
7367949, Jul 07 2003 Instrumentarium Corp Method and apparatus based on combination of physiological parameters for assessment of analgesia during anesthesia or sedation
7369896, Oct 24 2002 Lockheed Martin Corporation Systems and methods for treating movement disorders
7371365, Apr 04 2000 Mayo Foundation for Medical Education and Research Methods for detecting parenchymal plaques in vivo
7373198, Jul 12 2002 BIONOVA TECHNOLOGIES INC Method and apparatus for the estimation of anesthetic depth using wavelet analysis of the electroencephalogram
7376453, Oct 06 1993 JPMorgan Chase Bank, National Association Signal processing apparatus
7376459, Aug 15 2005 BRAINWAVE SCIENCE INC System and method for P300-based concealed information detector having combined probe and target trials
7378056, Nov 09 2000 VTQ IP HOLDING CORPORATION Circuits for in vivo detection of biomolecule concentrations using fluorescent tags
7381185, May 10 2004 MedDorna, LLC Method and apparatus for detecting physiologic signals
7383070, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
7383237, May 01 1998 Health Discovery Corporation Computer-aided image analysis
7386347, Jun 24 2002 CHUNG, JONG-PIL Electric stimilator for alpha-wave derivation
7389144, Nov 07 2003 FLINT HILLS SCIENTIFIC, L L C Medical device failure detection and warning system
7392079, Nov 14 2001 Brown University Research Foundation Neurological signal decoding
7394246, Nov 24 2006 MAGQU CO , LTD Superconductive quantum interference device (SQUID) system for measuring magnetic susceptibility of materials
7395292, Oct 08 2003 Method for displaying spectral trends in complex signals
7396333, Aug 18 2003 Cardiac Pacemakers, Inc Prediction of disordered breathing
7399282, May 19 2000 Baycrest Centre for Geriatric Care System and method for objective evaluation of hearing using auditory steady-state responses
7400984, Apr 18 2003 Hitachi High-Technologies, Corp. Biomagnetic measurement apparatus
7403809, Mar 07 1997 Hitachi, Ltd. Biomagnetic field measuring method and apparatus
7403814, May 04 2001 University of Virginia Patent Foundation Method, apparatus, and computer program product for assessment of attentional impairments
7403815, Jun 04 2004 Drexel University Brain state recognition system
7403820, Aug 05 1998 DiLorenzo Biomedical, LLC Closed-loop feedback-driven neuromodulation
7407485, Jun 08 2004 Instrumentarium Corporation Monitoring pain-related responses of a patient
7409321, Jul 12 2000 Cornell Research Foundation, Inc. Method and system for analyzing multi-variate data using canonical decomposition
7418290, May 06 2003 Covidien LP System and method of assessment of the efficacy of treatment of neurological disorders using the electroencephalogram
7420033, Oct 26 2004 Agennix, Inc. Composition of lactoferrin related peptides and uses thereof
7422555, Dec 30 2003 Systems and methods for therapeutically treating neuro-psychiatric disorders and other illnesses
7429247, Jul 07 2004 Sanyo Electric Co. Ltd. Sleep state estimating device and program product
7437196, Nov 12 2004 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for selecting stimulation sites and applying treatment, including treatment of symptoms of Parkinson's disease, other movement disorders, and/or drug side effects
7440789, Nov 18 2003 Nexstim Oy Electrode structure for measuring electrical responses from the human body
7440806, Nov 21 2000 Boston Scientific Neuromodulation Corporation Systems and methods for treatment of diabetes by electrical brain stimulation and/or drug infusion
7444184, May 11 2003 Neuro and Cardiac Technologies, LLC Method and system for providing therapy for bulimia/eating disorders by providing electrical pulses to vagus nerve(s)
7450986, Feb 28 2001 UNIVERSITY OF TECHNOLOGY SYDNEY Non-invasive method and apparatus for determining onset of physiological conditions
7453263, May 09 2006 BIOMAGNETIK PARK HOLDING GMBH Reference current optimizing apparatus for controlling magnetic flux-voltage conversion characteristic of double relaxation oscillation squid
7454240, Mar 07 1991 JPMorgan Chase Bank, National Association Signal processing apparatus
7454243, Aug 21 2003 SSPT PTY LTD Aptitude testing
7454245, Jan 28 2005 LivaNova USA, Inc Trained and adaptive response in a neurostimulator
7454387, Sep 15 2003 AVAGO TECHNOLOGIES GENERAL IP SINGAPORE PTE LTD Method of isolating sources of variance in parametric data
7457653, Oct 26 2001 National Institute of Information and Communications Technology Method of solving magnetoencephalographic and electroencephalographic inverse problems
7457665, Apr 30 1999 Flint Hills Scientific, L.L.C. Vagal nerve stimulation techniques for treatment of epileptic seizures
7461045, Aug 18 2003 Arizona Board of Regents Optimization of spatio-temporal pattern processing for seizure warning and prediction
7462151, Mar 02 1999 Quantum Intech, Inc. Method and apparatus for facilitating physiological coherence and autonomic balance
7462155, Oct 27 2004 Objective determination of chronic pain in patients
7463024, Mar 14 2003 Megin Oy Method and device for processing a multi-channel measurement of magnetic fields
7463142, Dec 30 2003 Binforma Group Limited Liability Company RFID system and method for tracking environmental data
7463927, Sep 02 2004 Intelligent Neurostimulation Microsystems, LLC Self-adaptive system for the automatic detection of discomfort and the automatic generation of SCS therapies for chronic pain control
7466132, Feb 06 2002 The Regents of the University of California Squid detected NMR and MRI at ultralow fields
7468040, Sep 18 2003 Cardiac Pacemakers, Inc. Methods and systems for implantably monitoring external breathing therapy
7468350, Jun 16 2004 EKOS LLC Glue composition for lung volume reduction
7469697, Sep 18 2003 Cardiac Pacemakers, Inc Feedback system and method for sleep disordered breathing therapy
7471971, Apr 14 1997 JPMorgan Chase Bank, National Association Signal processing apparatus and method
7471978, Aug 07 1997 New York University Brain function scan system
7478108, Dec 06 1999 Lord Corporation Data collection using sensing units and separate control units with all power derived from the control units
7482298, Nov 27 2006 Superconductor compositions operable at high temperatures
7483747, Jul 15 2004 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for enhancing or affecting neural stimulation efficiency and/or efficacy
7486986, Oct 12 1999 Flint Hills Scientific LLC Bi-directional cerebral interface system
7488294, Apr 01 2004 GOOGLE LLC Biosensors, communicators, and controllers monitoring eye movement and methods for using them
7489958, Apr 14 1997 JPMorgan Chase Bank, National Association Signal processing apparatus and method
7489964, Jul 11 2001 MYND ANALYTICS, INC , A CALIFORNIA CORPORATION Electroencephalography based systems and methods for selecting therapies and predicting outcomes
7490085, Dec 18 2002 GE Medical Systems Global Technology Company, LLC Computer-assisted data processing system and method incorporating automated learning
7491173, Oct 10 2001 Team Medical, LLC Method and system for obtaining dimension related information for a flow channel
7493171, Nov 21 2000 Boston Scientific Neuromodulation Corporation Treatment of pathologic craving and aversion syndromes and eating disorders by electrical brain stimulation and/or drug infusion
7493172, Jan 30 2001 Boston Scientific Neuromodulation Corporation Methods and systems for stimulating a nerve originating in an upper cervical spine area to treat a medical condition
7496393, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
7497828, Jan 10 1992 Wilk Ultrasound of Canada, Inc Ultrasonic medical device and associated method
7499741, Apr 14 1997 JPMorgan Chase Bank, National Association Signal processing apparatus and method
7499745, Feb 28 2000 DELPHINUS MEDICAL TECHNOLOGIES, INC Multidimensional bioelectrical tissue analyzer
7499752, Jul 29 2005 LivaNova USA, Inc Selective nerve stimulation for the treatment of eating disorders
7499894, Mar 13 2001 Cerebral programming
7502720, Sep 26 2003 Megin Oy Method and device for using a multi-channel measurement signal in source modelling
7509154, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
7509161, Oct 22 2003 Instrumentarium Corporation Method and apparatus for determining the cerebral state of a patient using generalized spectral entropy of the EEG signal
7509163, Sep 28 2007 International Business Machines Corporation Method and system for subject-adaptive real-time sleep stage classification
7510531, Sep 18 2003 Cardiac Pacemakers, Inc System and method for discrimination of central and obstructive disordered breathing events
7510699, Feb 19 2003 VTQ IP HOLDING CORPORATION In vivo fluorescence sensors, systems, and related methods operating in conjunction with fluorescent analytes
7515054, Apr 01 2004 GOOGLE LLC Biosensors, communicators, and controllers monitoring eye movement and methods for using them
7530955, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
7537568, Nov 11 1998 Spentech, Inc. Doppler ultrasound method and apparatus for monitoring blood flow
7539528, Sep 20 2002 Using magnetic resonance imaging to directly map neuronal activity
7539532, May 12 2006 KONINKLIJKE PHILIPS N V Cuffless blood pressure monitoring appliance
7539533, May 16 2006 KONINKLIJKE PHILIPS N V Mesh network monitoring appliance
7539543, Jun 11 1999 Cornell Research Foundation, Inc. Feedback method for deep brain stimulation with detection of generalized efference copy signals
7547284, Jan 14 2005 Atlantis Limited Partnership Bilateral differential pulse method for measuring brain activity
7553810, Jun 16 2004 EKOS LLC Lung volume reduction using glue composition
7558622, May 24 2006 KONINKLIJKE PHILIPS N V Mesh network stroke monitoring appliance
7559903, Mar 28 2007 TR TECHNOLOGIES INC Breathing sound analysis for detection of sleep apnea/popnea events
7561918, Jan 28 2005 LivaNova USA, Inc Autocapture in a neurostimulator
7565193, Jun 14 2004 CEPHOS CORP Questions and control paradigms for detecting deception by measuring brain activity
7565199, Dec 09 2002 ADVANCED NEUROMODULATION SYSTEMS, INC Methods for treating and/or collecting information regarding neurological disorders, including language disorders
7565200, Nov 12 2004 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for selecting stimulation sites and applying treatment, including treatment of symptoms of Parkinson's disease, other movement disorders, and/or drug side effects
7565809, Feb 03 2003 Japan Science and Technology Agency Circulation-type liquid helium reliquefaction apparatus with contaminant discharge function, method of discharging contaminant from the apparatus, and refiner and transfer tube both of which are used for the apparatus
7567693, Jan 30 2001 Methods for physiological monitoring training, exercise and regulation
7570054, Apr 20 2006 The General Hospital Corporation Dynamic magnetic resonance inverse imaging using linear constrained minimum variance beamformer
7570991, Nov 13 2007 WAVESYNCH TECHNOLOGIES, INC Method for real time attitude assessment
7572225, Sep 18 2003 Cardiac Pacemakers, Inc Sleep logbook
7573264, Nov 28 2005 The Regents of the University of California Atomic magnetic gradiometer for room temperature high sensitivity magnetic field detection
7573268, Feb 22 2006 Triad National Security, LLC Direct imaging of neural currents using ultra-low field magnetic resonance techniques
7574007, Mar 17 2000 INTERACOUSTICS A S Stimulus analysis system and method having adaptive artifact rejection
7574254, Nov 13 2007 WaveSynch Technologies, Inc.; WAVESYNCH TECHNOLOGIES, INC Method for monitoring attentiveness and productivity in a subject
7577472, Mar 18 2005 THE MEDICAL COLLEGE OF WISCONSIN, INC MRI method for producing an index indicative of brain disorders
7577481, Jul 13 2000 ADVANCED NEUROMODULATION SYSTEMS, INC Methods and apparatus for effectuating a lasting change in a neural-function of a patient
7580798, May 15 2001 Psychogenics, Inc.; Carnegie Mellon University Method for predicting treatment classes using animal behavior informatics
7582062, Sep 12 2003 Medical Research Council Methods of neural centre location and electrode placement in the central nervous system
7583857, Aug 24 2005 Siemens Medical Solutions USA, Inc System and method for salient region feature based 3D multi modality registration of medical images
7593767, Jun 15 2006 CLEVELAND MEDICAL DEVICES Ambulatory sleepiness and apnea propensity evaluation system
7594122, Nov 13 2007 WaveSynch Technologies, Inc.; WAVESYNCH TECHNOLGIES, INC Method of determining whether a test subject is a specific individual
7594889, Mar 31 2005 Medtronic, Inc Integrated data collection and analysis for clinical study
7596535, Sep 29 2003 BIOTRONIK GMBH & CO KG Apparatus for the classification of physiological events
7597665, Feb 28 2000 Ultrasonic medical device and associated method
7603168, Apr 17 2008 BioNova Technologies Inc. Method and apparatus for the estimation of anesthesia depth
7603174, Oct 21 2004 Advanced Neuromodulation Systems, Inc. Stimulation of the amygdalohippocampal complex to treat neurological conditions
7604603, Mar 26 2002 adidas AG Method and system for extracting cardiac parameters from plethysmographic signals
7606405, Aug 05 2003 IMQUANT, LLC Dynamic tumor diagnostic and treatment system
7608579, Jun 16 2004 EKOS LLC Lung volume reduction using glue compositions
7610083, Apr 27 2006 Medtronic, Inc. Method and system for loop recording with overlapping events
7610094, Sep 18 2003 Cardiac Pacemakers, Inc Synergistic use of medical devices for detecting medical disorders
7610096, Sep 04 2002 Washington University Methods for treating central nervous system damage
7610100, Dec 30 2005 Boston Scientific Neuromodulation Corporation Methods and systems for treating osteoarthritis
7613502, Oct 26 2004 Hitachi, Ltd. Optical bioinstrumentation for living body
7613519, Oct 21 2004 Advanced Neuromodulation Systems, Inc. Peripheral nerve stimulation to treat auditory dysfunction
7613520, Oct 21 2004 Advanced Neuromodulation Systems, Inc. Spinal cord stimulation to treat auditory dysfunction
7617002, Sep 15 2003 Medtronic, Inc. Selection of neurostimulator parameter configurations using decision trees
7618381, Oct 27 2004 Massachusetts Institute of Technology Wrist and upper extremity motion
7620455, Oct 25 2005 LivaNova USA, Inc Cranial nerve stimulation to treat eating disorders
7620456, Jul 13 2000 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for reducing the likelihood of inducing collateral neural activity during neural stimulation threshold test procedures
7623912, Sep 19 2002 RAMOT AT TEL AVIV UNIVERSITY LTD Method, apparatus and system for characterizing sleep
7623927, Dec 24 2002 CLEVELAND CLINIC FOUNDATION, THE Modulation of the brain to affect psychiatric disorders
7623928, Aug 05 1998 DiLorenzo Biomedical, LLC Controlling a subject's susceptibility to a seizure
7624293, Oct 15 2002 Medtronic, Inc. Synchronization and calibration of clocks for a medical device and calibrated clock
7625340, Dec 02 2004 Instrumentarium Corporation Identification of a dominant signal component in a biosignal
7627370, Oct 20 2004 Brain function decoding process and system
7629889, Dec 27 2006 Cardiac Pacemakers, Inc Within-patient algorithm to predict heart failure decompensation
7630757, Jan 06 1997 Flint Hills Scientific LLC System for the prediction, rapid detection, warning, prevention, or control of changes in activity states in the brain of a subject
7634317, Aug 31 2001 Medtronic, Inc Techniques for applying, calibrating, and controlling nerve fiber stimulation
7640055, Jan 07 2002 WIDEMED TECHNOLOGIES LTD Self-adaptive system for the analysis of biomedical signals of a patient
7643655, Nov 24 2000 Clever Sys, Inc. System and method for animal seizure detection and classification using video analysis
7643881, Dec 10 2004 LivaNova USA, Inc Neurostimulation with activation based on changes in body temperature
7647097, Dec 29 2003 BRAINGATE, INC Transcutaneous implant
7647098, Oct 31 2005 New York University System and method for prediction of cognitive decline
7648498, Feb 21 2005 Siemens Healthcare GmbH Irradiation device for influencing a biological structure in a subject with electromagnetic radiation
7649351, Feb 13 2004 Megin Oy Method for interference suppression in a measuring device
7653433, Jun 19 2003 Advanced Neuromodulation Systems, Inc. Method of treating depression, mood disorders and anxiety disorders using neuromodulation
7654948, Feb 28 2003 Consolidate Research of Richmond, Inc.; CONSOLIDATED RESEARCH OF RICHMOND, INC Automated insomnia treatment system
7657316, Feb 25 2005 Boston Scientific Neuromodulation Corporation Methods and systems for stimulating a motor cortex of the brain to treat a medical condition
7668579, Feb 10 2006 System and method for the detection of physiologic response to stimulation
7668591, Sep 18 2003 Cardiac Pacemakers, Inc Automatic activation of medical processes
7670838, May 24 2004 The Board of Trustees of the Leland Stanford Junior University Coupling of excitation and neurogenesis in neural stem/progenitor cells
7672707, Jun 11 2003 Japan Science and Technology Agency Sensor for magnetoencephalography meter and supermultichannel magnetoencephalography meter system using the same
7672717, Oct 22 2003 BIONOVA TECHNOLOGIES INC Method and system for the denoising of large-amplitude artifacts in electrograms using time-frequency transforms
7672730, Mar 08 2001 ADVANCED NEUROMODULATION SYSTEMS, INC Methods and apparatus for effectuating a lasting change in a neural-function of a patient
7676263, Jun 23 2006 DiLorenzo Biomedical, LLC Minimally invasive system for selecting patient-specific therapy parameters
7678047, Nov 13 2001 Electronic Navigation Research Institute; MITSUBISHI SPACE SOFTWARE CO , LTD Chaologic brain function diagnosis apparatus
7678061, Sep 18 2003 Cardiac Pacemakers, Inc System and method for characterizing patient respiration
7678767, Jun 16 2004 EKOS LLC Glue compositions for lung volume reduction
7680526, Jul 07 2004 The Cleveland Clinic Foundation System and method for obtaining a volume of influence based on non-uniform tissue conductivity data
7680540, Jul 29 2005 Medtronic, Inc Multi-application trial stimulator
7684856, Dec 12 2005 General Electric Company Detection of artifacts in bioelectric signals
7684858, Sep 21 2005 Boston Scientific Neuromodulation Corporation Methods and systems for placing an implanted stimulator for stimulating tissue
7684866, Aug 01 2003 ADVANCED NEUROMODULATION SYSTEMS, INC Apparatus and methods for applying neural stimulation to a patient
7684867, Nov 01 2005 Boston Scientific Neuromodulation Corporation Treatment of aphasia by electrical stimulation and/or drug infusion
7697979, Oct 18 2002 Centre National de la Recherche Scientifique Analysis method and real time medical or cognitive monitoring device based on the analysis of a subject's cerebral electromagnetic activity use of said method for characterizing and differentiating physiological or pathological states
7702387, Jun 08 2006 Greatbatch Ltd Tank filters adaptable for placement with a guide wire, in series with the lead wires or circuits of active medical devices to enhance MRI compatibility
7702502, Feb 23 2005 MURATA VIOS, INC Apparatus for signal decomposition, analysis and reconstruction
7706871, May 06 2003 Covidien LP System and method of prediction of response to neurological treatment using the electroencephalogram
7706992, Feb 23 2005 MURATA VIOS, INC System and method for signal decomposition, analysis and reconstruction
7711417, Oct 23 2002 New York University System and method for guidance of anesthesia, analgesia and amnesia
7711432, Jul 26 2004 ADVANCED NEUROMODULATION SYSTEMS, INC Stimulation system and method for treating a neurological disorder
7714936, May 13 1991 Sony Corporation Omniview motionless camera orientation system
7715894, Nov 07 2006 CONOPCO, INC D B A UNILEVER Apparatus and method for acquiring a signal
7715910, Feb 04 2002 HARGROVE, JEFFREY B Method and apparatus for utilizing amplitude-modulated pulse-width modulation signals for neurostimulation and treatment of neurological disorders using electrical stimulation
7715919, Oct 15 2002 Medtronic, Inc Control of treatment therapy during start-up and during operation of a medical device system
7720519, Oct 17 2002 Elekta Neuromag Oy Method for three-dimensional modeling of the skull and internal structures thereof
7720530, Aug 02 2005 BRAINSCOPE SPV LLC Field-deployable concussion detector
7725174, Jun 28 2006 The University of Utah; The University of Utah Research Foundation Distinguishing different drug effects from the electroencephalogram
7725192, Oct 12 2005 The General Hospital Corporation Methods of increasing learning rate
7727161, Apr 10 2003 adidas AG Systems and methods for monitoring cough
7729740, Apr 15 2004 Triad National Security, LLC Noise cancellation in magnetoencephalography and electroencephalography with isolated reference sensors
7729753, Mar 14 2006 HEALTHCARE FINANCIAL SOLUTIONS, LLC, AS SUCCESSOR AGENT Automated analysis of a cardiac signal based on dynamical characteristics of the cardiac signal
7729755, Jun 14 2004 Cephos Corp. Questions and control paradigms for detecting deception by measuring brain activity
7729773, Oct 19 2005 ADVANCED NEUROMODULATION SYSTEMS, INC Neural stimulation and optical monitoring systems and methods
7733224, Jun 30 2006 BT WEARABLES LLC Mesh network personal emergency response appliance
7733973, Aug 19 2004 Nippon Telegraph and Telephone Corporation; The University of Tokyo Multichannel signal encoding method, its decoding method, devices for these, program, and its recording medium
7734334, May 17 2004 Beth Israel Deaconess Medical Center, Inc. Assessment of sleep quality and sleep disordered breathing based on cardiopulmonary coupling
7734340, Oct 21 2004 ADVANCED NEUROMODULATION SYSTEMS, INC Stimulation design for neuromodulation
7734355, Aug 31 2001 Medtronic, Inc Treatment of disorders by unidirectional nerve stimulation
7736382, Sep 09 2005 NERVESENSE LTD Apparatus for optical stimulation of nerves and other animal tissue
7737687, Oct 19 2005 Samsung Electronics Co., Ltd. Fluxgate sensor having conbzr magnetic core and fabrication method thereof
7738683, Jul 22 2005 CARESTREAM HEALTH, INC Abnormality detection in medical images
7740592, Apr 17 2000 The University of Sydney Method and apparatus for objective electrophysiological assessment of visual function
7742820, Nov 12 2004 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for selecting stimulation sites and applying treatment, including treatment of symptoms of parkinson's disease, other movement disorders, and/or drug side effects
7746979, Feb 10 2005 U S DEPARTMENT OF ENERGY Methods for assisting recovery of damaged brain and spinal cord and treating various diseases using arrays of x-ray microplanar beams
7747318, Dec 07 2006 NeuroPace, Inc Functional ferrule
7747325, Aug 05 1998 DiLorenzo Biomedical, LLC Systems and methods for monitoring a patient's neurological disease state
7747326, Apr 30 2004 Advanced Neuromodulation Systems, Inc. Method of treating mood disorders and/or anxiety disorders by brain stimulation
7747551, Feb 21 2007 DiLorenzo Biomedical, LLC Reduction of classification error rates and monitoring system using an artificial class
7749155, Aug 30 1996 Headwaters Inc Digital sound relaxation and sleep-inducing system and method
7751877, Nov 25 2003 BRAINGATE, INC Neural interface system with embedded id
7751878, Nov 10 2004 National Technology & Engineering Solutions of Sandia, LLC Real-time human collaboration monitoring and intervention
7753836, Jun 15 2006 The Trustees of Columbia University in the City of New York Systems and methods for inducing electric field pulses in a body organ
7754190, Sep 06 1997 MYND ANALYTICS, INC , A CALIFORNIA CORPORATION Method for determining drug effects using quantitative EEG
7756564, Jan 29 2003 National Institute of Information and Communications Technology Apparatus for measuring the neuro-magnetic field from a human brain and method for operating the same
7756568, Sep 30 1998 VTQ IP HOLDING CORPORATION Methods, systems, and associated implantable devices for dynamic monitoring of physiological and biological properties of tumors
7756584, Jul 13 2000 ADVANCED NEUROMODULATION SYSTEMS, INC Methods and apparatus for effectuating a lasting change in a neural-function of a patient
7757690, Sep 18 2003 Cardiac Pacemakers, Inc System and method for moderating a therapy delivered during sleep using physiologic data acquired during non-sleep
7758503, Jan 27 1997 LYNN, LAWRENCE ALLAN Microprocessor system for the analysis of physiologic and financial datasets
7763588, Jun 13 2003 MARS, INCORPORATED Method for increasing cognitive function and neurogenesis
7764987, Sep 02 2004 BIOTRONIK SE & CO KG Signal processing apparatus for physiological signals
7765088, Apr 27 2006 Medtronic, Inc. Peak data retention of signal data in an implantable medical device
7766827, Oct 30 1998 United States of America as represented by the Secretary of the Army Method and system for predicting human cognitive performance
7769424, Dec 28 2001 Japan Science and Technology Agency; ADVANCED TELECOMMUNICATIONS RESEARCH INSTITUTE INTERNATIONAL Intercerebral current source estimation method intercerebral current source estimation program recording medium containing the intercerebral current source estimation program and intercerebral current source estimation apparatus
7769431, Sep 30 1998 VTQ IP HOLDING CORPORATION Methods, systems, and associated implantable devices for detecting radiation in patients undergoing treatment for cancer
7769461, Dec 17 2004 Boston Scientific Neuromodulation Corporation Skull-mounted electrical stimulation system and method for treating patients
7769464, Apr 30 2007 Medtronic, Inc Therapy adjustment
7771341, Jan 22 2003 Electromagnetic brain animation
7771364, Jan 27 2004 SPIROCOR LTD Method and system for cardiovascular system diagnosis
7774052, Jun 13 2002 Compumedics Limited Methods and apparatus for monitoring consciousness
7774064, Dec 12 2003 Cardiac Pacemakers, Inc Cardiac response classification using retriggerable classification windows
7775993, Mar 16 2004 Medtronic, Inc Detecting sleep
7778490, Jan 13 2003 KONINKLIJKE PHILIPS ELECTRONICS, N V Method of image registration and medical image data processing apparatus
7778692, Sep 30 1998 VTQ IP HOLDING CORPORATION Methods, systems, and associated implantable devices for detecting radiation in patients undergoing treatment for cancer
7778693, Apr 06 2002 The United States of America as represented by the Department of Health and Human Services System and method for quantifying the dynamic response of a target system
7783362, Jun 20 2002 Boston Scientific Neuromodulation Corporation Vagus nerve stimulation via unidirectional propagation of action potentials
7787937, Sep 30 1998 VTQ IP HOLDING CORPORATION Methods, systems, and associated implantable devices for detecting radiation in patients undergoing treatment for cancer
7787946, Sep 18 2003 Cardiac Pacemakers, Inc Patient monitoring, diagnosis, and/or therapy systems and methods
7792575, Feb 10 2005 National Institute of Information and Communications Technology Language processing function measuring device
7794403, Apr 21 2004 MEAR HOLDING B V System for measuring pulsatile vascular resistance
7794406, Nov 22 2004 WIDEMED TECHNOLOGIES LTD Detection of cardiac arrhythmias using a photoplethysmograph
7797040, Dec 16 2004 California Institute of Technology Prosthetic devices and methods and systems related thereto
7800493, Jun 30 2003 Sony Corporation Communication apparatus and communication method
7801591, May 30 2000 Digital healthcare information management
7801592, Jun 15 2006 Heart rate variability as predictor of postoperative nausea and vomiting
7801593, Aug 23 2004 Board of Regents, The University of Texas System System, software, and method for detection of sleep-disordered breathing using an electrocardiogram
7801601, Jan 27 2006 LivaNova USA, Inc Controlling neuromodulation using stimulus modalities
7801686, Apr 24 2008 HARVEST BIO LLC Combination treatment alteration methods and systems
7803118, Nov 22 2004 WIDEMED TECHNOLOGIES LTD Detection of heart failure using a photoplethysmograph
7803119, Nov 22 2004 WIDEMED TECHNOLOGIES LTD Respiration-based prognosis of heart disease
7804441, Jul 13 2007 The United States of America as represented by the Secretary of the Navy Detection of concealed object by standing waves
7805203, Feb 22 2005 Medtronic, Inc Method for surgically implanting an electrode device
7809433, Aug 09 2005 adidas AG Method and system for limiting interference in electroencephalographic signals
7809434, Dec 03 2004 Covidien LP System and method for EEG imaging of cerebral activity using small electrode sets
7811279, Jul 16 2003 Programmable medical drug delivery systems and methods for delivery of multiple fluids and concentrations
7819794, Oct 21 2002 Method and apparatus for the treatment of physical and mental disorders with low frequency, low flux density magnetic fields
7819812, Dec 15 2004 NeuroPace, Inc Modulation and analysis of cerebral perfusion in epilepsy and other neurological disorders
7822481, Apr 30 2007 Medtronic, Inc Therapy adjustment
7829562, Jun 12 2003 M S SCIENCE CORPORATION Sigma ligands for neuronal regeneration and functional recovery
7831302, Mar 22 2003 Qinetiq Limited Monitoring electrical muscular activity
7831305, Oct 15 2001 ADVANCED NEUROMODULATION SYSTEMS, INC Neural stimulation system and method responsive to collateral neural activity
7834627, Nov 27 2006 Hitachi, Ltd.; The University of Tokyo NMR measurement system and NMR image processing system for neural fiber bundles with volume of interest (VOI) optimization
7835787, May 03 2002 TRUSTEES OF COLUMBIA UNIVERSITY IN THE CITY OF NEW YORK, THE Single trial detection in encephalography
7840039, Jul 01 2003 Compumedics Limited Method and system for displaying confidence intervals for source reconstruction
7840248, Jan 27 2003 Compumedics Limited Online source reconstruction for eeg/meg and ecg/mcg
7840250, Nov 13 2001 Magstim Group, Incorporated Method for neural current imaging
7840257, Jan 04 2003 Non Invasive Technology, Inc. Examination of biological tissue using non-contact optical probes
7840280, Jul 27 2005 LivaNova USA, Inc Cranial nerve stimulation to treat a vocal cord disorder
7841986, May 10 2006 Regents of the University of Minnesota Methods and apparatus of three dimensional cardiac electrophysiological imaging
7844324, Feb 14 2007 General Electric Company Measurement of EEG reactivity
7848803, Mar 14 2005 Boston Scientific Neuromodulation Corporation Methods and systems for facilitating stimulation of one or more stimulation sites
7852087, Aug 10 2007 Schlumberger Technology Corporation Removing effects of near surface geology from surface-to-borehole electromagnetic data
7853321, Mar 14 2005 Boston Scientific Neuromodulation Corporation Stimulation of a stimulation site within the neck or head
7853322, Dec 02 2005 Medtronic, Inc Closed-loop therapy adjustment
7853323, Sep 15 2003 Medtronic, Inc. Selection of neurostimulator parameter configurations using neural networks
7853329, Aug 05 1998 DiLorenzo Biomedical, LLC Monitoring efficacy of neural modulation therapy
7856264, Oct 19 2005 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for patient interactive neural stimulation and/or chemical substance delivery
7860548, Jul 07 2004 The Cleveland Clinic Foundation Tissue stimulation models, systems, devices, and methods
7860552, Oct 01 2004 The McLean Hospital Corporation CNS assay for prediction of therapeutic efficacy for neuropathic pain and other functional illnesses
7860561, Jun 04 2004 Cleveland Medical Devices Inc.; Cleveland Medical Devices Inc Method of quantifying a subject's wake or sleep state and system for measuring
7860570, Jun 20 2002 Boston Scientific Neuromodulation Corporation Implantable microstimulators and methods for unidirectional propagation of action potentials
7863272, Jun 12 2003 M S SCIENCE CORPORATION Sigma ligands for neuronal regeneration and functional recovery
7865234, Jun 04 2003 Cleveland Medical Devices Inc. Quantitative method for the therapeutic treatment of sleep disorders
7865235, Sep 12 2005 Emotiv Systems Pty Ltd Method and system for detecting and classifying the mental state of a subject
7865244, Dec 17 2004 Medtronic, Inc System and method for regulating cardiopulmonary triggered therapy to the brain
7869867, Oct 27 2006 LivaNova USA, Inc Implantable neurostimulator with refractory stimulation
7869884, Apr 26 2007 LivaNova USA, Inc Non-surgical device and methods for trans-esophageal vagus nerve stimulation
7869885, Apr 28 2006 LivaNova USA, Inc Threshold optimization for tissue stimulation therapy
7872235, Jan 13 2005 Spectrum Dynamics Medical Limited Multi-dimensional image reconstruction and analysis for expert-system diagnosis
7873411, Sep 01 2004 National Institute of Information and Communications Technology Interface device, interface method and control training device by the use of the interface device
7876938, Oct 06 2005 Siemens Healthcare GmbH System and method for whole body landmark detection, segmentation and change quantification in digital images
7878965, Jun 26 2001 Therapeutic methods using electromagnetic radiation
7879043, Nov 28 2006 ENCORE MEDICAL, L P System and method for preventing intraoperative fracture in cementless hip arthroplasty
7881760, Dec 20 2004 Sumitomo Heavy Industries, LTD Measuring structure for magneto encephalographic equipment with a superconducting magnetic-shield
7881770, Mar 01 2000 Medtronic Navigation, Inc. Multiple cannula image guided tool for image guided procedures
7881780, Jan 18 2005 BRAINGATE, INC Biological interface system with thresholded configuration
7882135, May 15 2001 Psychogenics, Inc. Method for predicting treatment classes using behavior informatics
7884101, Nov 19 2004 ARENA PHARMACEUTICALS, INC 3-phenyl-pyrazole derivatives as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
7887493, Sep 18 2003 Cardiac Pacemakers, Inc Implantable device employing movement sensing for detecting sleep-related disorders
7890155, Jan 04 2007 Siemens Medical Solutions USA, Inc Feature emphasis and contextual cutaways for image visualization
7890176, Jul 06 1998 Boston Scientific Neuromodulation Corporation Methods and systems for treating chronic pelvic pain
7890185, Aug 31 2001 Medtronic, Inc Treatment of disorders by unidirectional nerve stimulation
7891814, Jun 05 2007 National Institute of Advanced Industrial Science and Technology Mental fatigue detecting method and device
7892764, Nov 21 2006 Legacy Emanuel Hospital & Health Center System for seizure suppression
7894890, Feb 09 2007 NeuroPace, Inc Devices and methods for monitoring physiological information relating to sleep with an implantable device
7894903, Mar 24 2005 Systems and methods for treating disorders of the central nervous system by modulation of brain networks
7895033, Jun 04 2004 HONDA RESEARCH INSTITUTE EUROPE GMBH System and method for determining a common fundamental frequency of two harmonic signals via a distance comparison
7896807, Oct 29 2004 Worcester Polytechnic Institute Multi-channel electrophysiologic signal data acquisition system on an integrated circuit
7899524, Jun 14 2004 MUSC Foundation for Research Development Systems and methods for detecting deception by measuring brain activity
7899525, Oct 23 2002 New York University System and method for guidance of anesthesia, analgesia and amnesia
7899539, Jun 20 2002 Boston Scientific Neuromodulation Corporation Cavernous nerve stimulation via unidirectional propagation of action potentials
7899545, Aug 31 2005 Methods and systems for semi-automatic adjustment of medical monitoring and treatment
7901211, Sep 04 2002 Method of treating autism using brain jogging system
7904134, Jul 07 2004 The Cleveland Clinic Foundation Brain stimulation models, systems, devices, and methods
7904139, Aug 26 1999 Non-Invasive Technology Inc. Optical examination of biological tissue using non-contact irradiation and detection
7904144, Aug 02 2005 BRAINSCOPE SPV LLC Method for assessing brain function and portable automatic brain function assessment apparatus
7904151, Feb 18 2005 Medtronic, Inc Parasympathetic stimulation for treating ventricular arrhythmia
7904175, Apr 26 2007 LivaNova USA, Inc Trans-esophageal vagus nerve stimulation
7904507, May 23 2008 The Invention Science Fund I, LLC Determination of extent of congruity between observation of authoring user and observation of receiving user
7907994, Jan 11 2007 Biosense Webster, Inc Automated pace-mapping for identification of cardiac arrhythmic conductive pathways and foci
7907998, Jul 03 2002 TEL-AVIV UNIVERSITY FUTURE TECHNOLOGY DEVELOPMENT Bio-impedance apparatus and method
7908008, Feb 22 2005 Medtronic, Inc Treatment for disorders by parasympathetic stimulation
7908009, Nov 12 2004 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for selecting stimulation sites and applying treatment, including treatment of symptoms of Parkinson's disease, other movement disorders, and/or drug side effects
7909771, Aug 28 2006 BIOTRONIK SE & CO KG Diagnosis of sleep apnea
7912530, Oct 14 2005 Hitachi High-Technologies Corporation Magnetic detection coil and apparatus for measurement of magnetic field
7917199, Nov 02 2004 Medtronic, Inc Patient event marking in combination with physiological signals
7917206, Oct 15 2002 Medtronic, Inc. Signal quality monitoring and control for a medical device system
7917221, Apr 17 2003 Forschungszentrum Julich GmbH Device for the desynchronization of neuronal brain activity
7917225, Nov 12 2004 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for selecting stimulation sites and applying treatment, including treatment of symptoms of parkinson's disease, other movement disorders, and/or drug side effects
7918779, Jun 26 2001 Photomed Technologies, Inc. Therapeutic methods using electromagnetic radiation
7920914, Apr 12 2007 Yuan Ze University Method for monitoring the depth of anesthesia
7920915, Nov 16 2005 Boston Scientific Neuromodulation Corporation Implantable stimulator
7920916, Nov 09 2006 Greatbatch Ltd. Capacitor and inductor elements physically disposed in series whose lumped parameters are electrically connected in parallel to form a bandstop filter
7925353, Mar 28 2003 MEDTRONIC MINIMED, INC Treatment of movement disorders with drug therapy
7929693, Apr 25 2005 Sony Corporation Key generating method and key generating apparatus
7930035, Aug 05 1998 DiLorenzo Biomedical, LLC Providing output indicative of subject's disease state
7932225, Jun 16 2004 EKOS LLC Glue composition for lung volume reduction
7933645, Mar 31 2005 The United States of America as represented by the Secretary of the Navy Use of EEG to measure cerebral changes during computer-based motion sickness-inducing tasks
7933646, Oct 15 2002 Medtronic, Inc. Clustering of recorded patient neurological activity to determine length of a neurological event
7933727, Apr 28 2005 Megin Oy Method and device for interference suppression in electromagnetic multi-channel measurement
7937138, Jan 20 2003 Cortical Dynamics Limited Method of monitoring brain function
7937152, Aug 30 2006 Functional Neuroscience, Inc. Systems and methods for treating pain using brain stimulation
7937222, Dec 02 2008 SCHLUMBERGER TECHNOPLOGY CORPORATION; Saudia Arabian Oil Company Method of determining saturations in a reservoir
7938782, Aug 18 2003 Cardiac Pacemakers, Inc. Prediction of disordered breathing
7938785, Dec 27 2007 TELEDYNE SCIENTIFIC & IMAGING, LLC Fusion-based spatio-temporal feature detection for robust classification of instantaneous changes in pupil response as a correlate of cognitive response
7941209, May 07 2004 OBS Medical Limited Signal analysis method
7942824, Nov 04 2005 Cleveland Medical Devices Inc.; Cleveland Medical Devices Inc Integrated sleep diagnostic and therapeutic system and method
7944551, Jun 30 2008 NELLCOR PURITAN BENNETT IRELAND Systems and methods for a wavelet transform viewer
7945304, Nov 20 2001 Ultrasound within MRI scanners for guidance of MRI pulse sequences
7945316, Dec 17 2004 Medtronic, Inc System and method for monitoring or treating nervous system disorders
7945330, Jul 13 2000 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for automatically optimizing stimulus parameters and electrode configurations for neuro-stimulators
7957796, Oct 28 2005 LivaNova USA, Inc Using physiological sensor data with an implantable medical device
7957797, Dec 02 2005 Medtronic, Inc Closed-loop therapy adjustment
7957806, Mar 19 2009 Greatbatch Ltd. Shielded three-terminal flat-through EMI/energy dissipating filter
7957809, Dec 02 2005 Medtronic, Inc Closed-loop therapy adjustment
7961922, May 31 2007 The Board of Regents of the University of Texas System Systems and methods for processing medical image data to facilitate comparisons among groups of subjects
7962204, Jul 11 2001 MYND ANALYTICS, INC , A CALIFORNIA CORPORATION Method of recommending neurophysiological therapies
7962214, Apr 26 2007 LivaNova USA, Inc Non-surgical device and methods for trans-esophageal vagus nerve stimulation
7962219, Feb 25 2005 Boston Scientific Neuromodulation Corporation Methods and systems for stimulating a motor cortex of the brain to treat a medical condition
7962220, Apr 28 2006 LivaNova USA, Inc Compensation reduction in tissue stimulation therapy
7970734, Dec 06 1999 Lord Corporation Data collection and storage device
7972278, Apr 17 2000 The University of Sydney Method and apparatus for objective electrophysiological assessment of visual function
7974688, Jan 28 2005 CYBERONICS, INC. Trained and adaptive response in a neurostimulator
7974693, Aug 31 2001 Medtronic, Inc Techniques for applying, configuring, and coordinating nerve fiber stimulation
7974696, Aug 05 1998 DiLorenzo Biomedical, LLC Closed-loop autonomic neuromodulation for optimal control of neurological and metabolic disease
7974697, Jan 26 2006 LivaNova USA, Inc Medical imaging feedback for an implantable medical device
7974701, Apr 27 2007 LivaNova USA, Inc Dosing limitation for an implantable medical device
7974787, Apr 24 2008 HARVEST BIO LLC Combination treatment alteration methods and systems
7976465, Oct 15 2002 Medtronic, Inc Phase shifting of neurological signals in a medical device system
7983740, Dec 22 2006 Washington University High performance imaging system for diffuse optical tomography and associated method of use
7983741, Jul 10 2002 Non-Invasive Technology Inc. Examination and imaging of brain cognitive functions
7983757, Oct 26 2007 Medtronic, Inc Medical device configuration based on sensed brain signals
7983762, Jul 15 2004 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for enhancing or affecting neural stimulation efficiency and/or efficacy
7986991, Oct 31 2005 New York University System and method for prediction of cognitive decline
7988613, Oct 21 2002 Method and apparatus for the treatment of physical and mental disorders with low frequency, low flux density magnetic fields
7988969, Aug 29 2001 Mayo Foundation for Medical Education and Research Treatment for central nervous system disorders
7991461, Jan 06 2005 BRAINGATE, INC Patient training routine for biological interface system
7991477, Sep 04 2002 Washington University Methods for treating central nervous system damage
7993279, Sep 18 2003 Cardiac Pacemakers, Inc. Methods and systems for implantably monitoring external breathing therapy
7996075, Oct 20 2004 HEALTHCARE FINANCIAL SOLUTIONS, LLC, AS SUCCESSOR AGENT Monitoring physiological activity using partial state space reconstruction
7996079, Jan 24 2006 LivaNova USA, Inc Input response override for an implantable medical device
8000767, Jan 20 2004 Board of Trustees of the University of Illinois Magneto-optical apparatus and method for the spatially-resolved detection of weak magnetic fields
8000773, Nov 09 2004 Spectrum Dynamics Medical Limited Radioimaging
8000788, Apr 27 2007 Medtronic, Inc Implantable medical device for treating neurological conditions including ECG sensing
8000793, Dec 24 2003 Cardiac Pacemakers, Inc. Automatic baroreflex modulation based on cardiac activity
8000794, Dec 23 2003 FUNCTIONAL NEUROSCIENCE INC Method and apparatus for affecting neurologic function and/or treating Neurologic dysfunction through timed neural stimulation
8000795, Dec 17 2004 FUNCTIONAL NEUROMODULATION INC Cognitive function within a human brain
8001179, May 23 2008 The Invention Science Fund I, LLC Acquisition and presentation of data indicative of an extent of congruence between inferred mental states of authoring users
8002553, Aug 18 2003 Cardiac Pacemakers, Inc Sleep quality data collection and evaluation
8005534, Jan 12 2005 Covidien LP System and method for prediction of adverse events during treatment of psychological and neurological disorders
8005624, Apr 26 2004 STARR Life Sciences Corp. Medical devices and techniques for rodent and small mammalian based research
8005894, May 23 2008 The Invention Science Fund I, LLC Acquisition and presentation of data indicative of an extent of congruence between inferred mental states of authoring users
8010178, Oct 05 2006 Hitachi, Ltd. Biomagnetic field measurement apparatus having a plurality of magnetic pick-up coils
8010347, Feb 23 2005 MURATA VIOS, INC Signal decomposition, analysis and reconstruction apparatus and method
8012107, Feb 05 2004 SANDLEFORD PARK LIMITED, AS SECURITY AGENT Methods and apparatus for rehabilitation and training
8014847, Dec 13 2001 MUSC Foundation for Research Development Systems and methods for detecting deception by measuring brain activity
8014870, Aug 11 2004 Method and apparatus for the treatment of tinnitus
8016597, Feb 25 2005 Brainon LLC System and method for interjecting bilateral brain activation into routine activity
8019400, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
8019410, Aug 22 2007 Pacesetter, Inc. System and method for detecting hypoglycemia using an implantable medical device based on pre-symptomatic physiological responses
8024029, Nov 02 2004 Medtronic, Inc Techniques for user-activated data retention in an implantable medical device
8024032, Nov 28 2005 FLINT HILLS SCIENTIFIC, L L C Method and system for the prediction, rapid detection, warning, prevention, or control of changes in the brain states of a subject using hurst parameter estimation
8025404, Nov 22 2000 BRAINSTEM BIOMETRICS Method and apparatus for monitoring eye tremor
8027730, Jan 21 2005 Systems and methods for treating disorders of the central nervous system by modulation of brain networks
8029553, Mar 02 2004 Portable laser and process for pain research
8031076, Dec 27 2006 Cardiac Pacemakers, Inc. Within-patient algorithm to predict heart failure decompensation
8032209, Sep 11 2003 Regents of the University of Minnesota Localizing neural sources in a brain
8032229, Apr 30 2007 Medtronic, Inc. Therapy adjustment
8032486, Dec 06 1999 Lord Corporation Apparatus to receive electromagnetic radiation that penetrates a housing formed of a conductive material
8033996, Jul 26 2005 adidas AG Computer interfaces including physiologically guided avatars
8036434, May 27 2005 SIEMENS HEALTHINEERS AG Post-processing of medical measurement data
8036728, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
8036736, Mar 21 2007 Cyberonics, Inc Implantable systems and methods for identifying a contra-ictal condition in a subject
8036745, Jun 10 2004 Medtronic, Inc Parasympathetic pacing therapy during and following a medical procedure, clinical trauma or pathology
8041136, Apr 21 2008 BRAINSCOPE SPV LLC System and method for signal processing using fractal dimension analysis
8041418, Dec 17 2004 Medtronic, Inc System and method for regulating cardiac triggered therapy to the brain
8041419, Dec 17 2004 Medtronic, Inc System and method for monitoring or treating nervous system disorders
8046041, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
8046042, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
8046076, Jun 20 2000 Boston Scientific Neuromodulation Corporation Treatment of mood and/or anxiety disorders by electrical brain stimulation and/or drug infusion
8050768, Jul 13 2000 ADVANCED NEUROMODULATION SYSTEMS, INC Methods and apparatus for effectuating a change in a neural-function of a patient
8055348, Mar 16 2004 Medtronic, Inc Detecting sleep to evaluate therapy
8055591, May 23 2008 The Invention Science Fund I, LLC Acquisition and association of data indicative of an inferred mental state of an authoring user
8059879, Oct 12 2005 Tokyo Denki University Brain function analysis apparatus and method
8060181, Apr 07 2006 Brainlab AG Risk assessment for planned trajectories
8060194, Jan 18 2005 BRAINGATE, INC Biological interface system with automated configuration
8064994, Jan 14 2003 U S DEPARTMENT OF VETERANS AFFAIRS Cervical vagal stimulation induced weight loss
8065011, Dec 12 2000 The Trustees of the University of Pennsylvania Adaptive method and apparatus for forecasting and controlling neurological disturbances under a multi-level control
8065012, Jul 13 2000 ADVANCED NEUROMODULATION SYSTEMS, INC Methods and apparatus for effectuating a lasting change in a neural-function of a patient
8065017, Feb 26 2007 Universidad Autonoma Metropolitana Unidad Iztapalapa Method and apparatus for obtaining and registering an Electrical Cochlear Response (“ECR”)
8065240, Oct 31 2007 WINTERLIGHT LABS INC Computational user-health testing responsive to a user interaction with advertiser-configured content
8065360, May 23 2008 The Invention Science Fund I, LLC Acquisition and particular association of inference data indicative of an inferred mental state of an authoring user and source identity data
8066637, Mar 02 1999 Quantum Intech, Inc. Method and apparatus for facilitating physiological coherence and autonomic balance
8066647, Dec 23 2004 ResMed Pty Ltd Method for detecting and discriminating breathing patterns from respiratory signals
8068904, Feb 09 2007 NeuroPace, Inc. Devices and methods for monitoring physiological information relating to sleep with an implantable device
8068911, Dec 17 2004 Medtronic, Inc System and method for regulating cardiopulmonary triggered therapy to the brain
8069125, Dec 20 2007 The Invention Science Fund I, LLC Methods and systems for comparing media content
8073534, May 10 2005 SALK INSTITUTE FOR BIOLOGICAL STUDIES, THE Automated detection of sleep and waking states
8073546, Mar 08 2001 Advanced Neuromodulation Systems, Inc. Methods and apparatus for effectuating a lasting change in a neural-function of a patient
8073631, Jul 22 2005 Psigenics Corporation Device and method for responding to influences of mind
8075499, May 18 2007 SMART MONITOR CORP Abnormal motion detector and monitor
8079953, Jun 17 1996 MEDCOM NETWORK SYSTEMS, LLC General-purpose medical instrumentation
8082031, Aug 08 2008 OCHSLABS LLC Neurofeedback system
8082033, Apr 13 2005 Cleveland Clinic Foundation System and method for providing a waveform for stimulating biological tissue
8082215, Sep 19 2008 The Invention Science Fund I, LLC Acquisition and particular association of inference data indicative of inferred mental states of authoring users
8083786, May 22 2003 MEDOC LTD Thermal stimulation probe and method
8086294, Oct 20 2000 The Trustees of the University of Pennsylvania Unified probabilistic framework for predicting and detecting seizure onsets in the brain and multitherapeutic device
8086296, Apr 30 2002 BRAINSONIX, CORP Methods for modifying electrical currents in neuronal circuits
8086563, May 23 2008 The Invention Science Fund I, LLC Acquisition and particular association of data indicative of an inferred mental state of an authoring user
8088057, Feb 01 2005 Apparatus and methods to improve sleep, reduce pain and promote natural healing
8089283, Aug 10 2007 CONSOLIDATED RESEARCH OF RICHMOND, INC Apparatus and method for high-speed determination of bioelectric electrode impedances
8090164, Aug 25 2003 UNIVERSITY OF NORTH CAROLINA AT CHAPEL HILL, THE Systems, methods, and computer program products for analysis of vessel attributes for diagnosis, disease staging, and surgical planning
8092549, Sep 24 2004 GEARBOX, LLC Ciliated stent-like-system
8095209, Jan 06 2005 BRAINGATE, INC Biological interface system with gated control signal
8095210, Jan 19 2007 California Institute of Technology Prosthetic devices and methods and systems related thereto
8097926, Oct 07 2008 MEDIDATA SOLUTIONS, INC Systems, methods, and devices having stretchable integrated circuitry for sensing and delivering therapy
8099299, May 20 2008 General Electric Company System and method for mapping structural and functional deviations in an anatomical region
8103333, May 16 2006 KONINKLIJKE PHILIPS N V Mesh network monitoring appliance
8108033, Nov 02 2004 Medtronic, Inc Techniques for data retention upon detection of an event in an implantable medical device
8108036, May 24 2006 KONINKLIJKE PHILIPS N V Mesh network stroke monitoring appliance
8108038, Dec 17 2004 Medtronic, Inc System and method for segmenting a cardiac signal based on brain activity
8108039, Jul 13 2007 NeuroWave Systems Inc Method and system for acquiring biosignals in the presence of HF interference
8108042, Nov 09 2006 Greatbatch Ltd. Capacitor and inductor elements physically disposed in series whose lumped parameters are electrically connected in parallel to form a bandstop filter
8112148, Dec 17 2004 Medtronic, Inc System and method for monitoring cardiac signal activity in patients with nervous system disorders
8112153, Dec 17 2004 Medtronic, Inc System and method for monitoring or treating nervous system disorders
8114021, Apr 28 2006 OTSUKA PHARMACEUTICAL CO , LTD Body-associated receiver and method
8116874, Dec 16 2004 Forschungzentrum Julich GmbH; FORSCHUNGSZENTRUM JUELICH GMBH Method and device for desynchronizing neural brain activity, controller and method for treating neural and/or psychiatric disorders
8116877, Aug 30 2006 FUNCTIONAL NEUROSCIENCE, INC Systems and methods for treating pain using brain stimulation
8116883, Jun 04 2003 NuXcel2, LLC Intravascular device for neuromodulation
8121361, May 19 2006 QUEEN S MEDICAL CENTER,THE; UNIVERSITY OF HAWAII,THE; MEDICAL COLLEGE OF WISCONSIN, INC ; UWM RESEARCH FOUNDATION, INC Motion tracking system for real time adaptive imaging and spectroscopy
8121673, May 12 2006 KONINKLIJKE PHILIPS N V Health monitoring appliance
8121694, Oct 16 2007 Medtronic, Inc Therapy control based on a patient movement state
8121695, Jul 13 2000 Advanced Neuromodulation Systems, Inc. Systems and methods for reducing the likelihood of inducing collateral neural activity during neural stimulation threshold test procedures
8126228, Jun 18 2008 International Business Machines Corporation Determining efficacy of therapeutic intervention in neurosychiatric disease
8126243, Aug 23 2005 NIHON MEDI-PHYSICS CO , LTD Image processing method, image processing program, and image processing device
8126528, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
8126542, Dec 10 2008 Somaxis, Inc. Methods for performing physiological stress tests
8126567, Apr 30 2007 Medtronic, Inc. Therapy adjustment
8126568, Mar 28 2002 ADVANCED NEUROMODULATION SYSTEMS, INC Electrode geometries for efficient neural stimulation
8128572, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
8131354, Jul 03 2002 TEL-AVIV UNIVERSITY FUTURE TECHNOLOGY DEVELOPMENT Apparatus and method for estimating stroke volume of the heart using bio-impedance techniques
8131526, Apr 14 2007 Schlumberger Technology Corporation System and method for evaluating petroleum reservoir using forward modeling
8133172, Dec 23 2008 Pharmaco-Kinesis Corporation Brain retractor apparatus for measuring and predicting electrophysiological parameters
8135472, May 29 2008 ADVANCED NEUROMODULATION SYSTEMS, INC Systems and methods for treating autism spectrum disorders (ASD) and related dysfunctions
8135957, Aug 23 2006 Siemens Aktiengesellschaft Access control system based on brain patterns
8137269, Sep 15 2004 K S HIMPP Method and system for managing physiological system
8137270, Nov 18 2003 adidas AG Method and system for processing data from ambulatory physiological monitoring
8140152, Dec 07 2006 NeuroPace, Inc. Functional ferrule
8145295, Apr 12 2006 GEARBOX, LLC Methods and systems for untethered autofluorescent imaging, target ablation, and movement of untethered device in a lumen
8145310, Dec 11 2003 Cardiac Pacemakers, Inc. Non-captured intrinsic discrimination in cardiac pacing response classification
8148417, May 18 2006 ARENA PHARMACEUTICALS, INC Primary amines and derivatives thereof as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
8148418, May 18 2006 ARENA PHARMACEUTICALS, INC Ethers, secondary amines and derivatives thereof as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
8150508, Mar 29 2006 Catholic Healthcare West; CATHOLIC HEALTHCARE WEST D B A ST JOSEPH S HOSPITAL AND MEDICAL CENTER Vagus nerve stimulation method
8150523, Jun 11 1999 Cornell Research Foundation, Inc. Feedback method for deep brain stimulation with detection of generalized efference copy signals
8150524, Oct 28 2005 LivaNova USA, Inc Selective neurostimulation for treating epilepsy
8150796, Dec 20 2007 The Invention Science Fund I, LLC Methods and systems for inducing behavior in a population cohort
8152732, May 17 2001 Microprocessor system for the analysis of physiologic and financial datasets
8155726, Nov 26 2007 Hitachi, LTD Magnetic detection coil and apparatus for magnetic field measurement
8155736, Mar 16 2009 NEUROSKY, INC EEG control of devices using sensory evoked potentials
8160273, Feb 26 2007 Qualcomm Incorporated Systems, methods, and apparatus for signal separation using data driven techniques
8160317, Dec 05 2005 Forschungszentrum Julich GmbH Method for topographical presentation of alterations in an examined brain
8160680, Apr 12 2006 GEARBOX, LLC Autofluorescent imaging and target ablation
8160689, Apr 01 2003 Sunstar Suisse SA Method of and apparatus for monitoring of muscle activity
8160696, Oct 03 2008 NERVESENSE LTD Nerve stimulator and method using simultaneous electrical and optical signals
8165687, Feb 26 2008 Universidad Autonoma Metropolitana, Unidad Iztapalapa Systems and methods for detecting and using an electrical cochlear response (“ECR”) in analyzing operation of a cochlear stimulation system
8167784, Dec 03 2007 Apparatus and methods to generate circadian rhythm based pulsed electromagnetic fields using micro-watts of electrical energy
8167826, Feb 03 2009 ACTION RESEARCH CO , LTD Vibration generating apparatus and method introducing hypersonic effect to activate fundamental brain network and heighten aesthetic sensibility
8170315, Feb 19 2007 Wisconsin Alumni Research Foundation Localized and highly constrained image reconstruction method
8170347, Sep 07 2006 Siemens Medical Solutions USA, Inc ROI-based assessment of abnormality using transformation invariant features
8172759, Apr 24 2009 LivaNova USA, Inc Methods and systems for detecting epileptic events using nonlinear analysis parameters
8172766, Nov 04 2005 Cleveland Medical Devices Inc.; Cleveland Medical Devices, Inc Integrated sleep diagnosis and treatment device and method
8174430, Jul 13 2007 The United States of America, as represented by the Secretary of the Navy Detection of concealed object by standing waves
8175359, Feb 19 2007 Wisconsin Alumni Research Foundation Iterative highly constrained image reconstruction method
8175360, Aug 31 2005 GE Healthcare Limited Method and system of multivariate analysis on normalized volume-wise data in the sinogram domain for improved quality in positron emission tomography studies
8175686, Jul 31 2007 Hitachi, LTD External condition control device based on measurement of brain functions
8175696, Jun 06 2006 CORTICAL DYNAMICS PTY LTD Brain function monitoring and display system
8175700, Nov 09 2006 Greatbatch Ltd Capacitor and inductor elements physically disposed in series whose lumped parameters are electrically connected in parallel to form a bandstop filter
8177724, Jun 08 2006 adidas AG System and method for snore detection and confirmation
8177726, Feb 08 2002 Rapid screening, threshold, and diagnostic tests for evaluation of hearing
8177727, Sep 20 2006 EARLOGIC KOREA INC ; KWAK, SANGYEOP Method and device for objective automated audiometry
8180125, May 20 2008 General Electric Company Medical data processing and visualization technique
8180148, Jan 26 2005 STICHTING AMSTERDAM UMC Imaging apparatus and method of forming composite image from a plurality of source images
8180420, Apr 14 1997 JPMorgan Chase Bank, National Association Signal processing apparatus and method
8180436, Apr 12 2006 GEARBOX, LLC Systems for autofluorescent imaging and target ablation
8180601, Mar 09 2006 CLEVELAND CLINIC FOUNDATION, THE Systems and methods for determining volume of activation for deep brain stimulation
8185186, Apr 13 2007 The Regents of the University of Michigan Systems and methods for tissue imaging
8185207, Oct 26 2007 Medtronic, Inc. Medical device configuration based on sensed brain signals
8185382, Jun 04 2004 HONDA RESEARCH INSTITUTE EUROPE GMBH Unified treatment of resolved and unresolved harmonics
8187181, Oct 15 2002 Medtronic, Inc Scoring of sensed neurological signals for use with a medical device system
8187201, Jan 27 1997 System and method for applying continuous positive airway pressure
8188749, Aug 10 2007 Schlumberger Technology Corporation Removing effects of near surface geology from surface-to-borehole electromagnetic data
8190227, Apr 14 1997 JPMorgan Chase Bank, National Association Signal processing apparatus and method
8190248, Oct 16 2003 Precisis GmbH Medical devices for the detection, prevention and/or treatment of neurological disorders, and methods related thereto
8190249, Aug 01 2005 Infinite Biomedical Technologies, LLC Multi-parametric quantitative analysis of bioelectrical signals
8190251, Mar 24 2006 Medtronic, Inc Method and apparatus for the treatment of movement disorders
8190264, Jun 19 2003 Advanced Neuromodulation Systems, Inc. Method of treating depression, mood disorders and anxiety disorders using neuromodulation
8195295, Mar 20 2008 Greatbatch Ltd Shielded three-terminal flat-through EMI/energy dissipating filter
8195298, Feb 15 2008 ADVANCED NEUROMODULATION SYSTEMS, INC D B A ST JUDE MEDICAL NEUROMODULATION DIVISION Method for treating neurological/psychiatric disorders with stimulation to the subcaudate area of the brain
8195300, Jul 13 2000 Advanced Neuromodulation Systems, Inc. Systems and methods for automatically optimizing stimulus parameters and electrode configurations for neuro-stimulators
8195593, Dec 20 2007 The Invention Science Fund I, LLC Methods and systems for indicating behavior in a population cohort
8197395, Jul 14 2004 Arizona Board of Regents For and On Behalf Of Arizona State University Pacemaker for treating physiological system dysfunction
8197437, Nov 16 2004 Bayer HealthCare LLC Systems and methods of modeling pharmaceutical propagation in a patient
8199982, Jun 18 2008 International Business Machines Corporation Mapping of literature onto regions of interest on neurological images
8199985, Mar 24 2006 Exini Diagnostics Aktiebolag Automatic interpretation of 3-D medicine images of the brain and methods for producing intermediate results
8200319, Feb 10 2009 HEALTHCARE FINANCIAL SOLUTIONS, LLC, AS SUCCESSOR AGENT Locating fiducial points in a physiological signal
8200340, Jul 11 2008 Medtronic, Inc Guided programming for posture-state responsive therapy
8204583, Oct 23 2007 Optima Neuroscience, Inc.; OPTIMA NEUROSCIENCE, INC System for seizure monitoring and detection
8204603, Apr 25 2008 LivaNova USA, Inc Blocking exogenous action potentials by an implantable medical device
8209009, Dec 17 2004 Medtronic, Inc System and method for segmenting a cardiac signal based on brain stimulation
8209018, Mar 10 2006 Medtronic, Inc Probabilistic neurological disorder treatment
8209019, Dec 17 2004 Medtronic, Inc System and method for utilizing brain state information to modulate cardiac therapy
8209224, Oct 29 2009 Nielsen Consumer LLC Intracluster content management using neuro-response priming data
8211035, Jan 22 2002 UNIVERSITY OF FLORIDA RESEARCH FOUNDATION, INC System and method for monitoring health using exhaled breath
8212556, Jan 12 2010 National Technology & Engineering Solutions of Sandia, LLC Atomic magnetometer
8213670, Jun 07 2007 AcousticSheep, LLC Sleep aid system and method
8214007, Nov 01 2006 FITLINXX, INC Body worn physiological sensor device having a disposable electrode module
8214035, Dec 17 2004 Medtronic, Inc System and method for utilizing brain state information to modulate cardiac therapy
8219188, Mar 29 2006 Catholic Healthcare West; CATHOLIC HEALTHCARE WEST D B A ST JOSEPH S HOSPITAL AND MEDICAL CENTER Synchronization of vagus nerve stimulation with the cardiac cycle of a patient
8221330, Feb 14 2007 General Electric Company Measurement for EEG reactivity
8222378, Jul 14 1998 Janssen Pharmaceutica N.V. Neurotrophic growth factor, enovin
8223023, Dec 27 2006 Cardiac Pacemakers, Inc. Within-patient algorithm to predict heart failure decompensation
8224431, Nov 02 2004 Medtronic, Inc Techniques for selective channel processing and data retention in an implantable medical device
8224433, Jul 11 2001 MYND ANALYTICS, INC , A CALIFORNIA CORPORATION Electroencephalography based systems and methods for selecting therapies and predicting outcomes
8224444, Feb 18 2005 Medtronic, Inc Intermittent electrical stimulation
8224451, Mar 14 2005 Boston Scientific Neuromodulation Corporation Methods and systems for facilitating stimulation of one or more stimulation sites
8229540, Jan 19 2004 Megin Oy Method for separating multichannel signals produced by AC and DC sources from one another
8229559, Jul 15 2010 Medtronic, Inc Evaluation of implantable medical device data
8233682, Jun 05 2007 General Electric Company; The University of Notre Dame du lac; The Regents of the University of Michigan; Purdue Research Foundation Methods and systems for improving spatial and temporal resolution of computed images of moving objects
8233689, Aug 31 2005 GE Healthcare Limited Method and system of multivariate analysis on volume-wise data of reference structure normalized images for improved quality in positron emission tomography studies
8233965, Mar 08 2007 Oslo Universitetssykehus HF Tumor grading from blood volume maps
8233990, Sep 15 2003 Medtronic, Inc. Selection of neurostimulator parameter configurations using decision trees
8235907, Jan 10 1992 Wilk Ultrasound of Canada, Inc Ultrasonic medical device and associated method
8236005, Nov 28 2006 ENCORE MEDICAL, L P System and method for preventing intraoperative fracture in cementless hip arthroplasty
8236038, Apr 20 2006 PITTSBURGH - OF THE COMMONWEALTH SYSTEM OF HIGHER EDUCATION, UNIVERSITY OF; PITTSBURGH, UNIVERSITY OF Method and apparatus of noninvasive, regional brain thermal stimuli for the treatment of neurological disorders
8239014, May 12 2010 OCHSLABS LLC Sequential low energy neurofeedback treatment
8239028, Apr 24 2009 LivaNova USA, Inc Use of cardiac parameters in methods and systems for treating a chronic medical condition
8239029, Oct 21 2004 Advanced Neuromodulation Systems, Inc. Stimulation of the amygdalohippocampal complex to treat neurological conditions
8239030, Jan 06 2010 EVOKE NEUROSCIENCE, INC Transcranial stimulation device and method based on electrophysiological testing
8241213, Jan 27 1997 Microprocessor system for the analysis of physiologic datasets
8244340, Dec 22 2006 Natus Medical Incorporated Method, system and device for sleep stage determination using frontal electrodes
8244341, Aug 23 2007 TALLINN UNIVERSITY OF TECHNOLOGY; North Estonia Medical Centre Method and device for determining depressive disorders by measuring bioelectromagnetic signals of the brain
8244347, Mar 04 2005 Andres M., Lozano Methods and apparatus for effectuating a lasting change in a neural function of a patient, including via mechanical force on neural tissue
8244475, Dec 27 2007 TELEDYNE SCIENTIFIC & IMAGING, LLC Coupling human neural response with computer pattern analysis for single-event detection of significant brain responses for task-relevant stimuli
8244552, Sep 03 2009 FREEDE SOLUTIONS, INC Template development based on sensor originated reported aspects
8244553, Sep 03 2009 FREEDE SOLUTIONS, INC Template development based on sensor originated reported aspects
8248069, Mar 06 2007 The Regents of the University of California Detecting spin perturbations using magnetic resonance imaging
8249316, Feb 07 2005 Agency for Science, Technology and Research Component labeling
8249698, Aug 31 2004 University of Akron, The General diagnostic and real-time applications of discrete hermite functions to digital data
8249718, Jul 11 2008 Medtronic, Inc Programming posture state-responsive therapy with nominal therapy parameters
8249815, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8260426, Jan 25 2008 LivaNova USA, Inc Method, apparatus and system for bipolar charge utilization during stimulation by an implantable medical device
8262714, Aug 05 2008 ADVANCED NEUROMODULATION SYSTEMS, INC Techniques for selecting signal delivery sites and other parameters for treating depression and other neurological disorders, and associated systems and methods
8263574, Sep 29 2004 JAMES L SCHALLER, M D , P A Topical formulations for the treatment of depression with S adenosyl methionine
8267851, Jun 16 2009 James M, Kroll Method and apparatus for electrically generating signal for inducing lucid dreaming
8270814, Jan 21 2009 Nielsen Consumer LLC Methods and apparatus for providing video with embedded media
8271077, Aug 27 2008 Lockheed Martin Corporation Learning optimization using biofeedback
8280502, Feb 04 2002 HARGROVE, JEFFREY B Method and apparatus for utilizing amplitude-modulated pulse-width modulation signals for neurostimulation and treatment of neurological disorders using electrical stimulation
8280503, Oct 27 2008 EMG measured during controlled hand movement for biometric analysis, medical diagnosis and related analysis
8280505, Mar 29 2006 Catholic Healthcare West Vagus nerve stimulation method
8280514, Oct 31 2006 FUNCTIONAL NEUROSCIENCE INC Identifying areas of the brain by examining the neuronal signals
8280517, Sep 19 2008 Medtronic, Inc.; Medtronic, Inc Automatic validation techniques for validating operation of medical devices
8285351, Dec 29 2008 HydroElectron Ventures, Inc. High-Tc superconductivity of electron-doped water-cluster clathrates
8285368, Jul 10 2009 The Regents of the University of California Endoscopic long range fourier domain optical coherence tomography (LR-FD-OCT)
8290575, Dec 01 2006 OBS Medical Limited Biomedical signal morphology analysis method
8290596, Sep 26 2007 Medtronic, Inc Therapy program selection based on patient state
8295914, Nov 16 2004 Bayer HealthCare LLC Systems and methods of determining patient transfer functions and modeling patient response to a pharmaceutical injection
8295934, Nov 14 2006 DiLorenzo Biomedical, LLC Systems and methods of reducing artifact in neurological stimulation systems
8295935, Sep 21 2004 University of Florida Research Foundation, Inc. Multiple lead method for deep brain stimulation
8296108, Apr 02 2010 Yugen Kaisha Suwa Torasuto Time series data analyzer, and a computer-readable recording medium recording a time series data analysis program
8298078, Feb 28 2005 LNW GAMING, INC Wagering game machine with biofeedback-aware game presentation
8298140, Jun 15 2006 HYPO-SAFE A S Analysis of EEG signals to detect hypoglycaemia
8301222, Apr 15 2006 FORSCHUNGSZENTRUM JUELICH GMBH Device for measuring biomedical data of a test subject and method for stimulating the test subject using data processed in real time
8301232, Jun 08 2010 ALIVECOR, INC Wireless, ultrasonic personal health monitoring system
8301233, Mar 31 2009 Medtronic, Inc Detecting a condition of a patient using a probability-correlation based model
8301257, Apr 21 2008 Wisconsin Alumni Research Foundation Method for suppressing and reversing epileptogenesis
8303636, Aug 12 2009 SCHIFER, FREDRIC, DR Methods for treating psychiatric disorders using light energy
8304246, Feb 28 2006 MED-LIFE DISCOVERIES LP Methods for the diagnosis of dementia and other neurological disorders
8305078, Oct 09 2008 Triad National Security, LLC Method of performing MRI with an atomic magnetometer
8306607, Oct 30 2003 BOARD OF TRUSTEES OF THE LELAND STANFORD JUNIOR UNIVERSITY, THE Implantable sensing arrangement and approach
8306610, Apr 18 2006 Method and apparatus for analysis of psychiatric and physical conditions
8306627, Apr 27 2007 LivaNova USA, Inc Dosing limitation for an implantable medical device
8308646, Apr 18 2005 Mayo Foundation for Medical Education and Research Trainable diagnostic system and method of use
8308661, Mar 16 2004 Medtronic, Inc Collecting activity and sleep quality information via a medical device
8311622, Dec 01 2005 Neba Health, LLC Systems and methods for analyzing and assessing depression and other mood disorders using electroencephalographic (EEG) measurements
8311747, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8311748, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8311750, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8313441, Mar 11 2010 Dichonics Corporation Neuroaudiological central auditory test apparatus and method of differentiation of the neural correlates in PTSD, TBI, autism, ADHD, et al
8314707, Mar 30 2009 Tobii AB Eye closure detection using structured illumination
8315703, Apr 30 2008 ADVANCED NEUROMODULATION SYSTEMS, INC Methods for targeting deep brain sites to treat mood and/or anxiety disorders
8315704, Mar 14 2005 Boston Scientific Neuromodulation Corporation Stimulation of a stimulation site within the neck or head
8315710, Jul 11 2008 Medtronic, Inc Associating therapy adjustments with patient posture states
8315812, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8315813, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8315814, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8315962, Nov 25 2009 Leidos, Inc System and method for multiclass discrimination of neural response data
8315970, Oct 20 2008 NEUROCHIP CORPORATION, C O ZBX CORPORATION Method and rhythm extractor for detecting and isolating rhythmic signal features from an input signal using the wavelet packet transform
8320649, May 25 2006 ELMINDA LTD Neuropsychological spatiotemporal pattern recognition
8321150, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8323188, May 16 2006 KONINKLIJKE PHILIPS N V Health monitoring appliance
8323189, May 12 2006 Philips North America LLC Health monitoring appliance
8323204, Dec 27 2002 Cardiac Pacemakers, Inc. Medical event logbook system and method
8326418, Aug 20 2007 Medtronic, Inc Evaluating therapeutic stimulation electrode configurations based on physiological responses
8326420, Jul 11 2008 Medtronic, Inc Associating therapy adjustments with posture states using stability timers
8326433, May 15 2008 Boston Scientific Neuromodulation Corporation Clinician programmer system and method for calculating volumes of activation for monopolar and bipolar electrode configurations
8328718, May 12 2006 KONINKLIJKE PHILIPS N V Health monitoring appliance
8332017, Dec 01 2006 OBS Medical Limited Method of biomedical signal analysis including improved automatic segmentation
8332024, May 25 2007 Massachusetts Institute of Technology Low-power analog architecture for brain-machine interfaces
8332038, Mar 16 2004 Medtronic, Inc. Detecting sleep to evaluate therapy
8332041, Jul 11 2008 Medtronic, Inc Patient interaction with posture-responsive therapy
8332191, Jul 14 2009 Schlumberger Technology Corporation Correction factors for electromagnetic measurements made through conductive material
8334690, Aug 07 2009 GOVERNMENT OF THE UNITED STATES OF AMERICA, AS REPRESENTED BY THE SECRETARY OF COMMERCE, THE NATIONAL INSTITUTE OF STANDARDS AND TECHNOLOGY Atomic magnetometer and method of sensing magnetic fields
8335561, Jun 04 2003 Cleveland Medical Devices Inc. Quantitative method for assessment of excessive daytime sleepiness
8335664, Sep 18 2008 IMEC Method and system for artifact reduction
8335715, Nov 19 2009 Nielsen Consumer LLC Advertisement exchange using neuro-response data
8335716, Nov 19 2009 Nielsen Consumer LLC Multimedia advertisement exchange
8337404, Oct 01 2010 Flint Hills Scientific, LLC Detecting, quantifying, and/or classifying seizures using multimodal data
8340752, May 04 2001 University of Virginia Patent Foundation Method, apparatus and computer program product for assessment of attentional impairments
8340753, Nov 16 2007 Binaural beat augmented biofeedback system
8340771, Jul 26 2004 Advanced Neuromodulation Systems, Inc. Stimulation system and method treating a neurological disorder
8343026, Jun 26 2001 PHOTOMED TECHNOLOGIES, INC Therapeutic methods using electromagnetic radiation
8343027, Jan 30 2012 SOFPULSE, INC Methods and devices for providing electromagnetic treatment in the presence of a metal-containing implant
8343066, Sep 27 2007 Baylor College of Medicine Device and method for rapid measurement of repetition suppression in the brain
8346331, Oct 18 2005 Drexel University Deception detection and query methodology for determining deception via neuroimaging
8346342, Nov 16 2004 Bayer HealthCare LLC Systems and methods of determining patient physiological parameters from an imaging procedure
8346349, Jan 16 2008 Massachusetts Institute of Technology Method and apparatus for predicting patient outcomes from a physiological segmentable patient signal
8346354, Jul 28 2009 GEARBOX, LLC Determining a neuromodulation treatment regimen in response to contactlessly acquired information
8346365, Dec 17 2004 FUNCTIONAL NEUROMODULATION INC Cognitive function within a human brain
8350804, Apr 10 1996 Thought controlled system
8352023, Oct 23 2002 New York University System and method for guidance of anesthesia, analgesia and amnesia
8352031, Mar 10 2004 SANDLEFORD PARK LIMITED, AS SECURITY AGENT Protein activity modification
8353837, Dec 05 2004 NeuroPace, Inc. Modulation and analysis of cerebral perfusion in epilepsy and other neurological disorders
8354438, Aug 08 2001 Neurological functions
8354881, Jan 31 2007 Medtronic, Inc. Chopper-stabilized instrumentation amplifier
8355768, Dec 17 2007 California Institute of Technology Micromachined neural probes
8356004, Dec 20 2007 The Invention Science Fund I LLC Methods and systems for comparing media content
8356594, Oct 17 2003 ResMed Pty Ltd Methods and apparatus for heart failure treatment
8358818, Nov 16 2006 Vanderbilt University Apparatus and methods of compensating for organ deformation, registration of internal structures to images, and applications of same
8359080, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
8362780, Mar 16 2009 Schlumberger Technology Corporation Induction coil impedance modeling using equivalent circuit parameters
8364226, Oct 06 1993 JPMorgan Chase Bank, National Association Signal processing apparatus
8364254, Jan 28 2009 BRAINSCOPE SPV LLC Method and device for probabilistic objective assessment of brain function
8364255, Mar 10 2010 BRAINSCOPE SPV LLC Method and device for removing EEG artifacts
8364271, Mar 11 2004 Advanced Neuromodulation Systems, Inc. Electrical stimulation system and method for stimulating tissue in the brain to treat a neurological condition
8364272, Apr 30 2010 Medtronic, Inc Brain stimulation programming
8369940, Feb 09 2007 NeuroPace, Inc. Devices and methods for monitoring physiological information relating to sleep with an implantable device
8374411, May 19 2006 The Queen's Medical Center; The University of Hawaii; The Medical College of Wisconsin, Inc.; UWM Research Foundation, Inc. Motion tracking system for real time adaptive imaging and spectroscopy
8374412, Jun 07 2007 Toshiba Medical Systems Corporation Data processing apparatus, medical diagnostic apparatus, data processing method and medical diagnostic method
8374690, Mar 10 2009 ARI Licensing Apparatus for determining health of an individual
8374696, Sep 14 2005 UNIVERSITY OF FLORIDA RESEARCH FOUNDATION, INC Closed-loop micro-control system for predicting and preventing epileptic seizures
8374701, Jul 28 2009 GEARBOX, LLC Stimulating a nervous system component of a mammal in response to contactlessly acquired information
8374703, Jan 26 2009 InCube Labs, LLC Method and apparatus for the detection of aberrant neural-electric activity
8376965, Mar 19 2008 BRAIN ACTUATED TECHNOLOGIES, INC Method and apparatus for using biopotentials for simultaneous multiple control functions in computer systems
8379947, May 28 2010 International Business Machines Corporation Spatio-temporal image reconstruction using sparse regression and secondary information
8379952, Jul 07 2004 The Cleveland Clinic Foundation Method and device for displaying predicted volume of influence with patient-specific atlas of neural tissue
8380289, Nov 18 2010 TELEFLEX LIFE SCIENCES LLC Medical device location systems, devices and methods
8380290, Sep 30 1998 VTQ IP HOLDING CORPORATION Implantable devices for dynamic monitoring of physiological and biological properties of tumors
8380296, Sep 18 2003 Cardiac Pacemakers, Inc. Automatic activation of medical processes
8380314, Sep 26 2007 Medtronic, Inc Patient directed therapy control
8380316, Jan 06 2010 EVOKE NEUROSCIENCE, INC Transcranial stimulation device and method based on electrophysiological testing
8380658, May 23 2008 The Invention Science Fund I, LLC Determination of extent of congruity between observation of authoring user and observation of receiving user
8382667, Oct 01 2010 Flint Hills Scientific, LLC Detecting, quantifying, and/or classifying seizures using multimodal data
8386188, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8386244, Feb 23 2005 MURATA VIOS, INC Signal decomposition, analysis and reconstruction
8386312, May 01 2007 Nielsen Consumer LLC Neuro-informatics repository system
8386313, Aug 28 2007 Nielsen Consumer LLC Stimulus placement system using subject neuro-response measurements
8388529, Jul 08 2008 International Business Machines Corporation Differential diagnosis of neuropsychiatric conditions
8388530, May 30 2000 Personalized monitoring and healthcare information management using physiological basis functions
8388555, Jan 08 2010 Medtronic, Inc Posture state classification for a medical device
8391942, Oct 06 2008 Edwards Lifesciences Corporation Method and apparatus for determining cerebral desaturation in patients undergoing deep hypothermic circulatory arrest
8391956, Nov 18 2010 TELEFLEX LIFE SCIENCES LLC Medical device location systems, devices and methods
8391966, Mar 16 2009 NEUROSKY, INC Sensory-evoked potential (SEP) classification/detection in the time domain
8392250, Aug 09 2010 Nielsen Consumer LLC Neuro-response evaluated stimulus in virtual reality environments
8392251, Aug 09 2010 Nielsen Consumer LLC Location aware presentation of stimulus material
8392253, May 16 2007 Nielsen Consumer LLC Neuro-physiology and neuro-behavioral based stimulus targeting system
8392254, Aug 28 2007 Nielsen Consumer LLC Consumer experience assessment system
8392255, Aug 29 2007 Nielsen Consumer LLC Content based selection and meta tagging of advertisement breaks
8396542, Aug 25 2010 Angel Medical Systems, Inc. Parameter value rejection for a cardiac monitor
8396545, Feb 25 2008 Wisconsin Alumni Research Foundation Electrophysiological screens for cognitive modulators
8396546, Mar 05 2010 OSAKA UNIVERSITY; ADVANCED TELECOMMUNICATIONS RESEARCH INSTITUTE INTERNATIONAL; The University of Tokyo Machine control device, machine system, machine control method, and recording medium storing machine control program
8396557, Aug 05 1998 DiLorenzo Biomedical, LLC Extracranial monitoring of brain activity
8396565, Sep 15 2003 Medtronic, Inc. Automatic therapy adjustments
8396744, Aug 25 2010 Nielsen Consumer LLC Effective virtual reality environments for presentation of marketing materials
8398692, Jan 10 2007 The Board of Trustees of the Leland Stanford Junior University System for optical stimulation of target cells
8401624, Dec 03 2008 Biosense Webster, Inc ECG signal analysis tool
8401626, May 17 2004 Beth Israel Deaconess Medical Center, Inc. System and method for assessing sleep quality
8401634, May 24 2002 Boston Scientific Neuromodulation Corporation Treatment of movement disorders by brain stimulation
8401654, Jun 30 2006 Boston Scientific Neuromodulation Corporation Methods and systems for treating one or more effects of deafferentation
8401655, Oct 21 2004 Advanced Neuromodulation Systems, Inc. Stimulation design for neuromodulation
8401666, Jul 11 2008 Medtronic, Inc Modification profiles for posture-responsive therapy
8403848, May 17 2004 Beth Israel Deaconess Medical Center, Inc. Assessment of sleep quality and sleep disordered breathing based on cardiopulmonary coupling
8406838, Jul 20 2004 Apparatus for evaluating biological function, a method for evaluating biological function, a living body probe, a living body probe mounting device, a living body probe support device and a living body probe mounting accessory
8406841, Aug 20 2010 National Chiao Tung University Dry electrode for biomedical signal measuring sensor
8406848, Oct 06 2009 Seiko Epson Corporation Reconstructing three-dimensional current sources from magnetic sensor data
8406862, Aug 25 2010 Angel Medical Systems, Inc. Ischemia detection based on combination of parameters associated with different sensors
8406890, Apr 14 2011 Medtronic, Inc.; Medtronic, Inc Implantable medical devices storing graphics processing data
8412334, Jun 20 2000 Boston Scientific Neuromodulation Corporation Treatment of mood and/or anxiety disorders by electrical brain stimulation and/or drug infusion
8412335, Jul 13 2000 Advanced Neuromodulation Systems, Inc. Systems and methods for automatically optimizing stimulus parameters and electrode configurations for neuro-stimulators
8412337, Aug 30 2006 Functional Neuroscience, Inc. Systems and methods for treating pain using brain stimulation
8412338, Nov 18 2008 SetPoint Medical Corporation Devices and methods for optimizing electrode placement for anti-inflamatory stimulation
8412655, Nov 13 2007 ORIDION MEDICAL 1987 LTD Medical system, apparatus and method
8415123, Apr 19 2004 SOFPULSE, INC Electromagnetic treatment apparatus and method for angiogenesis modulation of living tissues and cells
8417344, Oct 24 2008 LivaNova USA, Inc Dynamic cranial nerve stimulation based on brain state determination from cardiac data
8423118, Jun 21 2007 Koninklijke Philips Electronics N.V. Model-based differential diagnosis of dementia and interactive setting of level of significance
8423125, Nov 09 2004 Spectrum Dynamics Medical Limited Radioimaging
8423144, Mar 20 2008 PROFESSOR DR PETER TASS Device and method for auditory stimulation
8423155, Mar 14 2005 Boston Scientific Neuromodulation Corporation Methods and systems for facilitating stimulation of one or more stimulation sites
8423297, Jul 22 2005 Psigenics Corporation Device and method for responding to influences of mind
8425415, May 12 2006 KONINKLIJKE PHILIPS N V Health monitoring appliance
8425583, Apr 20 2006 University of Pittsburgh - Of the Commonwealth System of Higher Education Methods, devices and systems for treating insomnia by inducing frontal cerebral hypothermia
8428696, Mar 06 2006 Keenly Health, LLC Ultra wideband monitoring systems and antennas
8428703, Aug 25 2010 Angel Medical Systems, Inc.; ANGEL MEDICAL SYSTEMS, INC Acute ischemia detection based on parameter value range analysis
8428704, Aug 25 2010 Angel Medical Systems, Inc. Threshold adjustment schemes for acute ischemia detection
8428726, Oct 30 2007 SYNAPSE BIOMEDICAL, INC Device and method of neuromodulation to effect a functionally restorative adaption of the neuromuscular system
8429225, May 23 2008 The Invention Science Fund I, LLC Acquisition and presentation of data indicative of an extent of congruence between inferred mental states of authoring users
8430805, Oct 02 2006 EMKINETICS, INC Method and apparatus for magnetic induction therapy
8430816, May 20 2008 General Electric Company System and method for analysis of multiple diseases and severities
8431537, Jun 16 2004 EKOS LLC Glue composition for lung volume reduction
8433388, Dec 13 2007 University of Kansas Source affine reconstruction for medical imaging
8433410, Mar 20 2008 Greatbatch Ltd Shielded three-terminal flat-through EMI/energy dissipating filter
8433414, Jul 13 2000 Advanced Neuromodulation Systems, Inc. Systems and methods for reducing the likelihood of inducing collateral neural activity during neural stimulation threshold test procedures
8433418, Oct 21 2004 Advanced Neuromodulation Systems, Inc. Peripheral nerve stimulation to treat auditory dysfunction
8435166, Oct 02 2006 EMKINETICS, INC Method and apparatus for magnetic induction therapy
8437843, Jun 16 2006 Cleveland Medical Devices Inc.; Cleveland Medical Devices Inc EEG data acquisition system with novel features
8437844, Aug 21 2006 Holland Bloorview Kids Rehabilitation Hospital Method, system and apparatus for real-time classification of muscle signals from self-selected intentional movements
8437861, Jul 11 2008 Medtronic, Inc Posture state redefinition based on posture data and therapy adjustments
8439845, Sep 25 2007 UROVAL, INC Obtaining measurements of muscle reflexes for diagnosis of patient symptoms
8442626, Jun 21 2010 Systems and methods for communicating with a computer using brain activity patterns
8444571, Sep 25 2007 Uroval, Inc.; UROVAL, INC Obtaining measurements of muscle reflexes for diagnosis of patient symptoms
8445021, Apr 04 2008 The Regents of the University of California Functionalized magnetic nanoparticles and methods of use thereof
8445851, Nov 09 2004 Spectrum Dynamics Medical Limited Radioimaging
8447392, Aug 21 2002 New York University Brain-machine interface systems and methods
8447407, Apr 30 2008 UNIVERSITY OF FLORIDA RESEARCH FOUNDATION, INC Method and system for detecting epileptogenesis
8447411, Jul 11 2008 Medtronic, Inc Patient interaction with posture-responsive therapy
8449471, May 24 2006 KONINKLIJKE PHILIPS N V Health monitoring appliance
8452387, Sep 16 2010 FLINT HILLS SCIENTIFIC, L L C Detecting or validating a detection of a state change from a template of heart rate derivative shape or heart beat wave complex
8452544, Mar 09 2007 Utility and method for the application of signal advance amplification to analog waveform or signal detection, acquisition and processing
8454555, Sep 19 2008 Aalborg Universitet Cardiac related neural activity
8456164, Nov 20 2010 Methods and apparatuses for 3D magnetic density imaging and magnetic resonance imaging
8456166, Dec 02 2008 Schlumberger Technology Corporation Single-well through casing induction logging tool
8456309, Dec 27 2006 Cardiac Pacemakers, Inc. Within-patient algorithm to predict heart failure decompensation
8457730, Nov 29 2006 PIXART IMAGING INC Techniques for determining hearing threshold
8457746, Dec 24 2003 Cardiac Pacemakers, Inc. Implantable systems and devices for providing cardiac defibrillation and apnea therapy
8457747, Oct 20 2008 LivaNova USA, Inc Neurostimulation with signal duration determined by a cardiac cycle
8461988, Oct 16 2005 BT WEARABLES LLC Personal emergency response (PER) system
8463006, Apr 17 2007 System and method for using three dimensional infrared imaging to provide detailed anatomical structure maps
8463007, Nov 18 2008 SYNC-RX, LTD.; SYNC-RX, LTD Automatic generation of a vascular skeleton
8463349, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
8463370, Jul 07 2003 Instrumentarium Corporation Method and apparatus based on combination of physiological parameters for assessment of analgesia during anesthesia or sedation
8463374, Jun 28 2007 University of Virginia Patent Foundation Method, system and computer program product for controlling complex rhythmic systems
8463378, Oct 17 2008 FORSCHUNGSZENTRUM JUELICH GMBH Device and method for conditioned desynchronizing stimulation
8463386, Apr 17 2003 Forschungszentrum Julich GmbH Device for the desynchronization of neuronal brain activity
8463387, Oct 21 2004 Advanced Neuromodulation Systems, Inc. Stimulation of the amygdalohippocampal complex to treat neurological conditions
8464288, Jan 21 2009 Nielsen Consumer LLC Methods and apparatus for providing personalized media in video
8465408, Aug 06 2009 WAVE NEUROSCIENCE, INC Systems and methods for modulating the electrical activity of a brain using neuro-EEG synchronization therapy
8467877, Jan 26 2009 InCube Labs, LLC Method for the detection and treatment of aberrant neural-electric activity
8467878, Jun 19 2003 Advanced Neuromodulation Systems, Inc. Method of treating depression, mood disorders and anxiety disorders using neuromodulation
8473024, Aug 12 2008 BRAINSCOPE SPV LLC Flexible headset for sensing brain electrical activity
8473044, Mar 07 2007 Nielsen Consumer LLC Method and system for measuring and ranking a positive or negative response to audiovisual or interactive media, products or activities using physiological signals
8473306, Oct 03 2007 Ottawa Hospital Research Institute Method and apparatus for monitoring physiological parameter variability over time for one or more organs
8473345, Mar 29 2007 Nielsen Consumer LLC Protocol generator and presenter device for analysis of marketing and entertainment effectiveness
8475354, Sep 25 2007 WAVE NEUROSCIENCE, INC Systems and methods for neuro-EEG synchronization therapy
8475368, May 12 2006 Philips North America LLC Health monitoring appliance
8475371, Sep 01 2009 VIVOMETRICS, INC Physiological monitoring garment
8475387, Jun 20 2006 adidas AG Automatic and ambulatory monitoring of congestive heart failure patients
8475506, Aug 13 2007 Lockheed Martin Corporation VCSEL array stimulator apparatus and method for light stimulation of bodily tissues
8478389, Apr 23 2010 VIVAQUANT, INC System for processing physiological data
8478394, Aug 16 2010 BRAINSCOPE SPV LLC Field deployable concussion assessment device
8478402, Oct 31 2008 Medtronic, Inc Determining intercardiac impedance
8478417, Nov 02 2004 Medtronic, Inc Techniques for data reporting in an implantable medical device
8478428, Apr 23 2010 LivaNova USA, Inc Helical electrode for nerve stimulation
8480554, Sep 25 2007 WAVE NEUROSCIENCE, INC Systems and methods for depression treatment using neuro-EEG synchronization therapy
8483795, Mar 03 2011 MOMENT TECHNOLOGIES, LLC Primary source mirror for biomagnetometry
8483815, Jun 06 2006 CORTICAL DYNAMICS PTY LTD EEG analysis system
8483816, Feb 03 2010 HRL Laboratories, LLC Systems, methods, and apparatus for neuro-robotic tracking point selection
8484081, Mar 29 2007 Nielsen Consumer LLC Analysis of marketing and entertainment effectiveness using central nervous system, autonomic nervous system, and effector data
8484270, Jun 12 2007 VIVOSONIC INC System and method for adaptive stimulus-response signal filtering
8485979, Dec 17 2004 Medtronic, Inc System and method for monitoring or treating nervous system disorders
8487760, Jul 09 2010 Nokia Technologies Oy Providing a user alert
8489185, Jul 02 2008 The Board of Regents, The University of Texas System Timing control for paired plasticity
8492336, Jul 14 1998 Janssen Pharmaceutica N.V. Methods of treating neuropathic pain with an environ polypeptide
8494610, Sep 20 2007 Nielsen Consumer LLC Analysis of marketing and entertainment effectiveness using magnetoencephalography
8494829, Jul 21 2010 VITAL METRIX INC Sensor fusion and probabilistic parameter estimation method and apparatus
8494857, Jan 06 2009 Regents of the University of Minnesota Automatic measurement of speech fluency
8494905, Jun 06 2007 Nielsen Consumer LLC Audience response analysis using simultaneous electroencephalography (EEG) and functional magnetic resonance imaging (fMRI)
8496594, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8498697, Oct 30 2009 VERSITECH LIMITED Classification of somatosensory evoked potential waveforms
8498699, Oct 03 2008 NERVESENSE LTD Method and nerve stimulator using simultaneous electrical and optical signals
8498708, Sep 13 2004 NEURONIX LTD Integrated system and method for treating disease using cognitive-training and brain stimulation and computerized magnetic photo-electric stimulator (CMPES)
8500282, Nov 22 2000 BRAINSTEM BIOMETRICS Method and apparatus for monitoring eye tremor
8500636, May 12 2006 KONINKLIJKE PHILIPS N V Health monitoring appliance
8504150, Jul 11 2008 Medtronic, Inc. Associating therapy adjustments with posture states using a stability timer
8506469, May 13 2008 Cerbomed GmbH Method to enhance neural tissue operation
8509879, Nov 06 2007 MODULATED IMAGING, INC Apparatus and method for widefield functional imaging (WiFI) using integrated structured illumination and laser speckle imaging
8509881, Nov 03 2009 ZOLL Medical Corporation True ECG measurement during cardio pulmonary resuscitation by adaptive piecewise stitching algorithm
8509885, Nov 30 2006 Neba Health LLC S and M for analyzing and assessing depression and other mood disorders using electoencephalograhic (EEG) measurements
8509904, May 27 2010 CORTEC GmbH BCI apparatus for stroke rehabilitation
8512219, Apr 19 2004 GEARBOX, LLC Bioelectromagnetic interface system
8512221, Feb 28 2003 CONSOLIDATED RESEARCH OF RICHLAND, INC Automated treatment system for sleep
8512240, Nov 14 2007 MEDASENSE BIOMETRICS LTD System and method for pain monitoring using a multidimensional analysis of physiological signals
8515535, Feb 28 2005 Cardiac Pacemakers, Inc. Implantable cardiac device with dyspnea measurement
8515538, Nov 07 2003 Flint Hills Scientific, LLC Medical device failure detection and warning system
8515541, Dec 22 2004 Boston Scientific Neuromodulation Corporation Methods and systems for treating post-stroke disorders
8515549, Jul 11 2008 Medtronic, Inc Associating therapy adjustments with intended patient posture states
8515550, Jul 11 2008 Medtronic, Inc Assignment of therapy parameter to multiple posture states
8517909, Feb 01 2005 Apparatus and methods to improve sleep, reduce pain and promote natural healing
8517912, Jul 20 2006 ZENZONE INTERACTIVE LIMITED Medical hypnosis device for controlling the administration of a hypnosis experience
8519705, Oct 09 2008 Triad National Security, LLC Method of performing MRI with an atomic magnetometer
8519853, Nov 05 2008 The George Washington University Unobtrusive driver drowsiness detection system and method
8520974, Jan 11 2008 Shimadzu Corporation; THE RITSUMEIKAN TRUST Image processing method, an apparatus therefor and a tomographic apparatus for removing artifacts from a sectional image
8521284, Dec 12 2003 Cardiac Pacemakers, Inc Cardiac response classification using multisite sensing and pacing
8523779, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8525673, Jun 30 2006 BT WEARABLES LLC Personal emergency response appliance
8525687, Jun 30 2006 BT WEARABLES LLC Personal emergency response (PER) system
8527029, Aug 09 2011 MOMENT TECHNOLOGIES, LLC Modular arrays of primary source mirrors for biomagnetometry
8527035, Apr 28 2008 THE TRUSTEES OF DARTMOUTH COLLEGE System, optode and cap for near-infrared diffuse-optical function neuroimaging
8527435, Jul 01 2003 CardioMag Imaging, Inc. Sigma tuning of gaussian kernels: detection of ischemia from magnetocardiograms
8529463, Apr 14 2008 The Johns Hopkins University Systems and methods for testing vestibular and oculomotor function
8531291, Oct 16 2005 BT WEARABLES LLC Personal emergency response (PER) system
8532756, Jun 13 2006 HEALTH RESEARCH, INC Method for analyzing function of the brain and other complex systems
8532757, Dec 16 2009 Medtronic, Inc Stimulation electrode selection
8533042, Jul 30 2007 Nielsen Consumer LLC Neuro-response stimulus and stimulus attribute resonance estimator
8536667, Oct 07 2008 MEDIDATA SOLUTIONS, INC Systems, methods, and devices having stretchable integrated circuitry for sensing and delivering therapy
8538108, Dec 20 2005 University of Maryland, Baltimore Method and apparatus for accelerated elastic registration of multiple scans of internal properties of a body
8538512, Apr 23 2007 NeuroWave Systems Inc. Method for amplifying abnormal pattern signal in observed brain activity of a subject for diagnosis or treatment
8538513, Dec 16 2009 Medtronic, Inc Stimulation electrode selection
8538514, Feb 09 2007 NeuroPace, Inc. Devices and methods for monitoring physiological information relating to sleep with an implantable device
8538523, Aug 20 2007 Medtronic, Inc. Evaluating therapeutic stimulation electrode configurations based on physiological responses
8538536, Apr 20 2007 The Cleveland Clinic Foundation Methods of improving neuropsychological function in patients with neurocognitive disorders
8538543, Jul 07 2004 The Cleveland Clinic Foundation System and method to design structure for delivering electrical energy to tissue
8538700, Jul 13 2010 Schlumberger Technology Corporation Method of determining subterranean formation parameters
8538705, Mar 31 2006 Covidien LP System and method of assessing analgesic adequacy using biopotential variability
8542900, Nov 18 2008 SYNC-RX, LTD Automatic reduction of interfering elements from an image stream of a moving organ
8542916, Jul 09 2008 Florida Atlantic University System and method for analysis of spatio-temporal data
8543189, Apr 23 2007 Medtronic Navigation, Inc. Method and apparatus for electromagnetic navigation of a magnetic stimulation probe
8543199, Mar 21 2007 Cyberonics, Inc Implantable systems and methods for identifying a contra-ictal condition in a subject
8543214, Oct 15 2002 Medtronic, Inc Configuring and testing treatment therapy parameters for a medical device system
8543219, Jul 29 2002 Forschungszentrum Julich GmbH Device for modulation of neuronal activity in the brain by means of sensory stimulation and detection of brain activity
8545378, Jun 15 2006 The Trustees of Columbia University in the City of New York Systems and methods for inducing electric field pulses in a body organ
8545416, Nov 04 2005 Cleveland Medical Devices Inc.; Cleveland Medical Devices Inc Integrated diagnostic and therapeutic system and method for improving treatment of subject with complex and central sleep apnea
8545420, Feb 05 2004 SANDLEFORD PARK LIMITED, AS SECURITY AGENT Methods and apparatus for rehabilitation and training
8545436, Dec 15 2008 PROTEUS DIGITAL HEALTH, INC Body-associated receiver and method
8548583, Mar 10 2004 SANDLEFORD PARK LIMITED, AS SECURITY AGENT Protein activity modification
8548594, Nov 17 2004 Advanced Neuromodulation Systems, Inc. Stimulation system and method treating a neurological disorder
8548604, Jun 20 2002 Boston Scientific Neuromodulation Corporation Implantable microstimulators and methods for unidirectional propagation of action potentials
8548786, Aug 12 2005 The Government of the United States of America Neuronal avalanche assay
8548852, Aug 25 2010 Nielsen Consumer LLC Effective virtual reality environments for presentation of marketing materials
8553956, Feb 28 2011 Seiko Epson Corporation 3D current reconstruction from 2D dense MCG images
8554311, Jun 17 2011 General Electric Company System and method of noise reduction in an electrocardiology study
8554325, Oct 16 2007 Medtronic, Inc. Therapy control based on a patient movement state
8559645, Dec 22 2009 SIVANTOS PTE LTD Method and device for setting a hearing device by detecting listening effort
8560034, Oct 06 1993 JPMorgan Chase Bank, National Association Signal processing apparatus
8560041, Oct 04 2004 BRAINGATE, INC Biological interface system
8560073, Mar 23 2009 Flint Hills Scientific, LLC System and apparatus for automated quantitative assessment, optimization and logging of the effects of a therapy
8562525, Jun 10 2010 Sony Corporation Biological signal processing apparatus, biological signal processing method, and biological signal processing program
8562526, Jun 01 2006 ResMed Sensor Technologies Limited Apparatus, system, and method for monitoring physiological signs
8562527, Jun 17 1996 MEDCOM NETWORK SYSTEMS, LLC General-purpose medical instrumentation
8562536, Apr 29 2010 LivaNova USA, Inc Algorithm for detecting a seizure from cardiac data
8562540, Dec 03 2004 GEARBOX, LLC Method and system for adaptive vision modification
8562548, Sep 23 2008 Honda Motor Co., Ltd. Rehabilitation device and controlling method thereof
8562660, Aug 05 2005 Methods to regulate polarization and enhance function of excitable cells
8562951, Sep 06 1997 MYND ANALYTICS, INC , A CALIFORNIA CORPORATION Methods for classifying and treating physiologic brain imbalances using quantitative EEG
8565606, Apr 22 2009 BIOMAGNETIK PARK HOLDING GMBH System and method for acquiring data of multi-channel squid signal
8565864, Nov 02 2004 Medtronic, Inc. Techniques for data retention upon detection of an event in an implantable medical device
8565867, Jan 28 2005 LivaNova USA, Inc Changeable electrode polarity stimulation by an implantable medical device
8565883, Dec 17 2004 Functional Neuromodulation Inc. Cognitive function within a human brain
8565886, Nov 10 2010 Medtronic, Inc.; Medtronic, Inc Arousal state modulation with electrical stimulation
8568231, Aug 27 2009 The Board of Regents of the University of Texas System Virtual reality entertainment system for treatment of phantom limb pain and methods for making and using same
8568329, Dec 31 2008 Industrial Technology Research Institute Baseline drift canceling method and device
8571293, May 19 2006 The Queen's Medical Center; The University of Hawaii; The Medical College of Wisconsin, Inc.; UWM Research Foundation, Inc. Motion tracking system for real time adaptive imaging and spectroscopy
8571629, Nov 13 2006 Truth Test Technologies, LLC Detection of deception and truth-telling using fMRI of the brain
8571642, Sep 14 2010 Pacesetter, Inc Pre-ejection interval (PEI) monitoring devices, systems and methods
8571643, Sep 16 2010 Flint Hills Scientific, LLC Detecting or validating a detection of a state change from a template of heart rate derivative shape or heart beat wave complex
8571653, Aug 31 2001 Medtronic, Inc Nerve stimulation techniques
8574164, Oct 20 2009 Nyxoah SA Apparatus and method for detecting a sleep disordered breathing precursor
8574279, Aug 12 2009 SCHIFER, FREDRIC, DR Methods for treating psychiatric disorders using light energy
8577103, Jul 16 2008 IMAGE RECON LLC Multimodal image reconstruction
8577464, Oct 20 2009 Nyxoah SA Apparatus and methods for feedback-based nerve modulation
8577465, Sep 30 2011 Nyxoah SA Modulator apparatus configured for implantation
8577466, Sep 30 2011 Nyxoah SA System and method for nerve modulation using noncontacting electrodes
8577467, Sep 30 2011 Nyxoah SA Apparatus and method for controlling energy delivery as a function of degree of coupling
8577468, Sep 30 2011 Nyxoah SA Apparatus and method for extending implant life using a dual power scheme
8577472, Oct 20 2009 Nyxoah SA Systems and methods for determining a sleep disorder based on positioning of the tongue
8577478, Sep 30 2011 Nyxoah SA Antenna providing variable communication with an implant
8579786, Oct 15 2002 Medtronic, Inc Screening techniques for management of a nervous system disorder
8579793, Jan 27 2010 Apparatus to affect brainwave entrainment over premises power-line wiring
8579795, Apr 30 2007 Light modulation device and system
8579834, Jan 08 2010 Medtronic, Inc. Display of detected patient posture state
8583238, Oct 02 2012 Great Lakes Neuro Technologies Inc.; Great Lakes Neurotechnologies Inc Wearable, unsupervised transcranial direct current stimulation (tDCS) device for movement disorder therapy, and method of using
8583252, Jul 11 2008 Medtronic, Inc Patient interaction with posture-responsive therapy
8585568, Nov 12 2009 WAVE NEUROSCIENCE, INC Systems and methods for neuro-EEG synchronization therapy
8586019, May 22 2008 Fundacion de la Comunidad Valenciana Centro de Investigacion Principe Felipe Conjugates of polymers having a therapeutically active agent and an angiogenesis targeting moiety attached thereto and uses thereof in the treatment of angiogenesis related diseases
8586932, Nov 09 2004 Spectrum Dynamics Medical Limited System and method for radioactive emission measurement
8587304, Sep 05 2007 Regents of the University of California, The Optical atomic magnetometer
8588486, Jun 18 2009 General Electric Company Apparatus and method for isolating a region in an image
8588552, May 28 2010 International Business Machines Corporation Spatio-temporal image reconstruction using sparse regression and secondary information
8588899, Mar 24 2010 SCHIFF, STEVEN J , DR Model based control of Parkinson's disease
8588929, Jul 11 2008 Medtronic, Inc. Posture state redefinition based on posture data and therapy adjustments
8588933, Jan 09 2009 Cyberonics, Inc Medical lead termination sleeve for implantable medical devices
8588941, Sep 30 2011 Nyxoah SA Device and method for modulating nerves using parallel electric fields
8589316, Aug 27 2009 The Cleveland Clinic Foundation System and method to estimate region of tissue activation
8591419, Jul 14 2008 Arizona Board of Regents For and On Behalf Of Arizona State University Methods and devices for modulating cellular activity using ultrasound
8591498, Jul 16 2003 Programmable medical drug delivery systems and methods for delivery of multiple fluids and concentrations
8593141, Nov 24 2009 THE JOHNSON REVOCABLE TRUST DATED 6 25 2003 Magnetic resonance system and method employing a digital squid
8593154, Dec 24 2010 General Electric Company System and method for artifact suppression in soft-field tomography
8594798, Oct 15 2002 Medtronic, Inc Multi-modal operation of a medical device system
8594800, Dec 04 2008 The Cleveland Clinic Foundation System and method to define target volume for stimulation of the spinal cord and peripheral nerves
8594950, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8597171, Apr 24 2007 CORNFIELD ELECTRONICS, INC Guide glasses
8597193, May 08 2003 TELEFLEX LIFE SCIENCES LLC Apparatus and method for endovascular device guiding and positioning using physiological parameters
8600493, Jul 25 2011 General Electric Company Method, apparatus and computer program product for automatic seizure monitoring
8600502, Aug 18 2003 Cardiac Pacemakers, Inc. Sleep state classification
8600513, Dec 09 2010 The Board of Trustees of the Leland Stanford Junior University Seizure prediction and neurological disorder treatment
8600521, Jan 27 2005 LivaNova USA, Inc Implantable medical device having multiple electrode/sensor capability and stimulation based on sensed intrinsic activity
8600696, Sep 28 2007 Method and system for determining a reaction signal for a selected location in an information processing system following the effect of at least one input signal
8603790, Apr 23 2008 The Board of Trustees of the Leland Stanford Junior University Systems, methods and compositions for optical stimulation of target cells
8606349, Nov 09 2004 Spectrum Dynamics Medical Limited Radioimaging using low dose isotope
8606351, Dec 28 2011 General Electric Company Compression of electrocardiograph signals
8606356, Sep 18 2003 Cardiac Pacemakers, Inc Autonomic arousal detection system and method
8606360, Mar 09 2006 The Cleveland Clinic Foundation Systems and methods for determining volume of activation for spinal cord and peripheral nerve stimulation
8606361, Jul 15 2004 Advanced Neuromodulation Systems, Inc. Systems and methods for enhancing or affecting neural stimulation efficiency and/or efficacy
8606530, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8606592, Apr 24 2008 HARVEST BIO LLC Methods and systems for monitoring bioactive agent use
8612005, Feb 01 2002 CLEVELAND CLINIC FOUNDATION, THE Neurostimulation for affecting sleep disorders
8613695, Jul 10 2008 Applied Magnetics, LLC Highly precise and low level signal-generating drivers, systems, and methods of use
8613905, Aug 30 2007 United Arab Emirates University Diagnostic agent
8614254, Mar 09 2007 New York University Methods and compositions for treating thalamocortical dysrhythmia
8614873, Apr 16 2010 JAMES T BERAN REVOCABLE TRUST DATED DECEMBER 26, 2002 Varying electrical current and/or conductivity in electrical current channels
8615293, Oct 09 2003 Jacobson Resonance Enterprises, Inc. Cardioelectromagnetic treatment
8615309, Mar 29 2006 Catholic Healthcare West; CATHOLIC HEALTHCARE WEST D B A ST JOSEPH S HOSPITAL AND MEDICAL CENTER Microburst electrical stimulation of cranial nerves for the treatment of medical conditions
8615479, Dec 13 2007 The Invention Science Fund I, LLC Methods and systems for indicating behavior in a population cohort
8615664, May 23 2008 The Invention Science Fund I, LLC Acquisition and particular association of inference data indicative of an inferred mental state of an authoring user and source identity data
8618799, Nov 24 2009 THE JOHNSON REVOCABLE TRUST DATED 6 25 2003 Magnetic resonance system and method employing a digital SQUID
8620206, May 23 1994 Robert Bosch Healthcare Systems, Inc. System and method for remote education
8620419, Sep 11 2009 Lockheed Martin Corporation Multi purpose criteria based adaptive training system
8626264, Apr 09 2008 JAMES T BERAN REVOCABLE TRUST DATED DECEMBER 26, 2002 Obtaining information about brain activity
8626301, Dec 24 2003 Cardiac Pacemakers, Inc. Automatic baroreflex modulation based on cardiac activity
8628328, Jan 31 2004 Linguaversal SL System, method, computer program and data set intended to facilitate the comprehension and/or learning of languages by utilizing modified versions
8628480, May 20 2005 adidas AG Methods and systems for monitoring respiratory data
8630699, Nov 01 2006 FITLINXX, INC Body worn physiological sensor device having a disposable electrode module
8630705, Nov 16 2005 Boston Scientific Neuromodulation Corporation Implantable stimulator
8630812, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8632465, Nov 03 2009 VIVAQUANT, INC Physiological signal denoising
8632750, Sep 06 1997 MYND ANALYTICS, INC , A CALIFORNIA CORPORATION Methods for recommending neurophysiological disorder therapy
8634616, Dec 04 2008 Koninklijke Philips Electronics N V Method, apparatus, and computer program product for acquiring medical image data
8634922, Apr 30 1999 Flint Hills Scientific, LLC Vagal nerve stimulation techniques for treatment of epileptic seizures
8635105, Aug 28 2007 Nielsen Consumer LLC Consumer experience portrayal effectiveness assessment system
8636640, Apr 11 2008 Brain Symphony LLC Method and system for brain entertainment
8638950, Aug 30 1996 Headwaters Inc Digital sound relaxation and sleep-inducing system and method
8641632, Nov 03 2004 Luc, Quintin; Andrei, Cividjian Method and device for predicting abnormal medical events and/or assisting in diagnosis and/or monitoring, particularly in order to determine depth of anesthesia
8641646, Jul 30 2010 LivaNova USA, Inc Seizure detection using coordinate data
8644754, May 23 1994 Robert Bosch Healthcare Systems, Inc. Method and apparatus for interactively monitoring a physiological condition and for interactively providing health-related information
8644910, Jul 19 2005 Spectrum Dynamics Medical Limited Imaging protocols
8644914, Jun 08 2007 Cardio-Qt Limited Methods of measurement of drug induced changes in cardiac ion channel function and associated apparatus
8644921, Mar 28 2011 MED-EL Elektromedizinische Geraete GmbH Neuromodulation system and method for treating apnea
8644945, Jul 11 2008 Medtronic, Inc Patient interaction with posture-responsive therapy
8644946, Dec 04 2008 The Cleveland Clinic Foundation System and method to define target volume for stimulation in brain
8644954, Mar 14 2005 Boston Scientific Neuromodulation Corporation Methods and systems for facilitating stimulation of one or more stimulation sites
8644957, Sep 30 2011 Nyxoah SA Electrode configuration for implantable modulator
8647278, Oct 26 2010 CHONGQING UNIVERSITY Method and system for non-invasive intracranial pressure monitoring
8648017, Nov 04 2009 DIAMIR, LLC Methods of using small RNA from bodily fluids for diagnosis and monitoring of neurodegenerative diseases
8649845, Oct 19 2010 The Cleveland Clinic Foundation Methods for identifying target stimulation regions associated with therapeutic and non-therapeutic clinical outcomes for neural stimulation
8649866, Feb 14 2008 Cardiac Pacemakers, Inc. Method and apparatus for phrenic stimulation detection
8649871, Apr 29 2010 Cyberonics, Inc Validity test adaptive constraint modification for cardiac data used for detection of state changes
8652038, May 12 2006 Philips North America LLC Health monitoring appliance
8652187, May 28 2010 NUROTONE MEDICAL LTD Cuff apparatus and method for optical and/or electrical nerve stimulation of peripheral nerves
8652189, May 22 2003 Medoc Ltd. Thermal stimulation probe and method
8655428, May 12 2010 Nielsen Consumer LLC Neuro-response data synchronization
8655437, Aug 21 2009 Nielsen Consumer LLC Analysis of the mirror neuron system for evaluation of stimulus
8655817, Feb 20 2008 DIGITAL MEDICAL EXPERTS INC Expert system for determining patient treatment response
8657732, Jan 30 2009 VASISHTA, VISHWANATH GOPALAKRISHNA Sequentially programmed magnetic field therapeutic system (SPMF)
8657756, Sep 18 2003 Cardiac Pacemakers, Inc. Implantable device employing movement sensing for detecting sleep-related disorders
8658149, May 22 2008 RAMOT AT TEL-AVIV UNIVERSITY LTD Conjugates of a polymer, a bisphosphonate and an anti-angiogenesis agent and uses thereof in the treatment and monitoring of bone related diseases
8660642, Apr 12 2006 GEARBOX, LLC Lumen-traveling biological interface device and method of use
8660649, Aug 13 2008 STARLAB BARCELONA S L Multi-site cranial stimulation method and system
8660666, Mar 29 2006 Catholic Healthcare West Microburst electrical stimulation of cranial nerves for the treatment of medical conditions
8660799, Jun 30 2008 NELLCOR PURITAN BENNETT IRELAND Processing and detecting baseline changes in signals
8664258, May 18 2006 Arena Pharmaceuticals, Inc. Primary amines and derivatives thereof as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
8666099, Apr 16 2010 WIDEX A S Hearing aid and a method for alleviating tinnitus using a notch filter
8666467, May 17 2001 Lawrence A., Lynn System and method for SPO2 instability detection and quantification
8666478, Oct 08 2009 THE MEDICAL COLLEGE OF WISCONSIN, INC Method for determining locations of implanted electrodes with medical images
8666501, Jul 02 2008 Board of Regents, The University of Texas System Methods, systems, and devices for treating tinnitus with VNS pairing
8668496, Feb 08 2012 Training system
8670603, Nov 18 2008 SYNC-RX, LTD. Apparatus and methods for masking a portion of a moving image stream
8672852, Dec 13 2002 2BREATHE TECHNOLOGIES LTD Apparatus and method for beneficial modification of biorhythmic activity
8675936, Jul 16 2008 IMAGE RECON LLC; Siemens Medical Solutions USA, Inc Multimodal image reconstruction
8675945, Mar 29 2011 Boston Scientific Neuromodulation Corporation System and method for image registration
8675983, Apr 15 2011 IMAGE RECON L L C Method to determine a pixon map in iterative image reconstruction and spectral analysis
8676324, Nov 10 2005 ElectroCore LLC Electrical and magnetic stimulators used to treat migraine/sinus headache, rhinitis, sinusitis, rhinosinusitis, and comorbid disorders
8676325, Dec 22 2006 MED-EL Elektromedizinische Geraete GmbH; Cornell University Adaptive airway treatment of dorsal displacement disorders in horses
8676330, Mar 20 2009 ElectroCore LLC Electrical and magnetic stimulators used to treat migraine/sinus headache and comorbid disorders
8679009, Jun 15 2010 Flint Hills Scientific, LLC Systems approach to comorbidity assessment
8680119, May 18 2006 Arena Pharmaceuticals, Inc. Ethers, secondary amines and derivatives thereof as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
8680991, Jun 30 2006 BT WEARABLES LLC Personal emergency response appliance
8682422, Aug 25 2010 Angel Medical Systems, Inc. Acute ischemia detection based on parameter value range analysis
8682441, Aug 30 2010 Advanced Neurostimulation Systems, Inc. Use of a new stimulation design to treat neurological disorder
8682449, Apr 10 2008 ElectroCore LLC Methods and apparatus for transcranial stimulation
8682687, Apr 24 2008 HARVEST BIO LLC Methods and systems for presenting a combination treatment
8684742, Apr 19 2010 Nielsen Consumer LLC Short imagery task (SIT) research method
8684900, May 16 2006 KONINKLIJKE PHILIPS N V Health monitoring appliance
8684921, Oct 01 2010 Flint Hills Scientific LLC; FLINT HILLS SCIENTIFIC, L L C Detecting, assessing and managing epilepsy using a multi-variate, metric-based classification analysis
8684922, Dec 07 2012 KONINKLIJKE PHILIPS N V Health monitoring system
8684926, Feb 25 2008 IDEAL INNOVATIONS INCORPORATED System and method for knowledge verification utilizing biopotentials and physiologic metrics
8688209, Sep 25 2006 Koninklijke Philips N.V. Device for ambulatory monitoring of brain activity
8690748, Aug 02 2010 Apparatus for measurement and treatment of a patient
8693756, Nov 18 2008 SYNC-RX, LTD. Automatic reduction of interfering elements from an image stream of a moving organ
8693765, Sep 05 2008 Commissariat a l Energie Atomique et aux Energies Alternatives Method for recognizing shapes and system implementing said method
8694087, May 28 2008 Cornell University Patient controlled brain repair system and method of use
8694089, Jul 03 2002 Tel Aviv University Future Technology Development L.P. Apparatus and method for estimating stroke volume of the heart using bio-impedance techniques
8694092, Apr 12 2006 GEARBOX, LLC Lumen-traveling biological interface device and method of use
8694107, Jun 27 2002 Method for eradicating pain of central origin resulting from spinal cord injury
8694118, Oct 28 2005 LivaNova USA, Inc Variable output ramping for an implantable medical device
8694157, Aug 29 2008 CORINDUS, INC Catheter control system and graphical user interface
8696722, Nov 22 2010 The Board of Trustees of the Leland Stanford Junior University Optogenetic magnetic resonance imaging
8696724, Jan 11 2007 SCION NEUROSTIM, INC Devices for vestibular or cranial nerve stimulation
8698639, Feb 18 2011 HONDA MOTOR CO , LTD System and method for responding to driver behavior
8700137, Aug 30 2012 ALIVECOR, INC. Cardiac performance monitoring system for use with mobile communications devices
8700141, Mar 10 2010 BRAINSCOPE SPV LLC Method and apparatus for automatic evoked potentials assessment
8700142, Aug 07 1997 New York University Brain function scan system
8700163, Mar 04 2005 ZABARA, JACOB Cranial nerve stimulation for treatment of substance addiction
8700167, Dec 22 2006 NEUROMODTRONIC GMBH Apparatus and method for stimulating a brain of a person
8700174, Jan 28 2011 Medtronic, Inc.; Medtronic, Inc Recharge coupling efficiency for patient posture state
8700183, Sep 30 2011 Nyxoah SA Devices and methods for low current neural modulation
8703114, May 22 2008 University of Utah Research Foundation Conjugate of a polymer, an anti-angiogenesis agent and a targeting moiety, and uses thereof in the treatment of bone related angiogenesis conditions
8706183, Jun 28 2007 PITTSBURGH UNIVERSITY OF - OF THE COMMONWEALTH SYSTEM OF HIGHER EDUCATION Electrode systems, devices and methods
8706205, Nov 29 2007 ELMINDA LTD Functional analysis of neurophysiological data
8706206, Oct 29 2009 Panasonic Corporation Human fatigue assessment device and human fatigue assessment method
8706207, Oct 08 2008 FLINT, ALEXANDER C Method and apparatus for measuring and treating shivering during therapeutic temperature control
8706237, Feb 19 2012 Medtronic, Inc.; Medtronic, Inc Brain stimulation response profiling
8706241, Oct 19 2005 Advanced Neuromodulation Systems, Inc. System for patent interactive neural stimulation with robotic facilitation of limb movement
8706518, Dec 30 2008 The Invention Science Fund I, LLC Methods and systems for presenting an inhalation experience
8708903, Mar 11 2013 KONINKLIJKE PHILIPS N V Patient monitoring appliance
8708934, Jul 11 2008 Medtronic, Inc Reorientation of patient posture states for posture-responsive therapy
8711655, Mar 17 2009 Schlumberger Technology Corporation Single well reservoir characterization apparatus and methods
8712507, Sep 14 2006 Cardiac Pacemakers, Inc Systems and methods for arranging and labeling cardiac episodes
8712512, Jul 27 2010 Cerebral Diagnostics Canada Incorporated Apparatus and method for exerting force on a subject tissue
8712513, Jun 04 2003 Cleveland Medical Devices Inc. Quantitative sleep analysis system and method
8712547, Jun 20 2002 Boston Scientific Neuromodulation Corporation Cavernous nerve stimulation via unidirectional propagation of action potentials
8716447, Nov 14 2008 The Board of Trustees of the Leland Stanford Junior University Optically-based stimulation of target cells and modifications thereto
8717430, Apr 26 2010 Medtronic Navigation, Inc. System and method for radio-frequency imaging, registration, and localization
8718747, Apr 16 2010 Oslo Universitetssykehus HF Estimating and correcting for contrast agent extravasation in tissue perfusion imaging
8718776, Sep 30 2011 Nyxoah SA Apparatus and method to control an implant
8718777, Nov 27 2002 Advanced Neuromodulation Systems, Inc. Methods and systems for intracranial neurostimulation and/or sensing
8718779, Jun 20 2000 Boston Scientific Neuromodulation Corporation Treatment of mood and/or anxiety disorders by electrical brain stimulation and/or drug infusion
8721695, Jun 18 2009 FORSCHUNGSZENTRUM JUELICH GMBH Device and method for stimulating neuronal tissue by means of optical stimuli
8724871, Dec 14 2011 ATTI International Services Company, Inc. Method and system for identifying anomalies in medical images
8725238, Sep 11 2009 Agency for Science, Technology and Research Electrocardiogram signal processing system
8725243, Dec 28 2005 DiLorenzo Biomedical, LLC Methods and systems for recommending an appropriate pharmacological treatment to a patient for managing epilepsy and other neurological disorders
8725311, Mar 14 2011 AMERICAN VEHICULAR SCIENCES LLC Driver health and fatigue monitoring system and method
8725668, Mar 24 2009 Regents of the University of Minnesota; Department of Veterans Affairs Classifying an item to one of a plurality of groups
8725669, Aug 02 2010 Signal processing method and apparatus
8725796, Jul 07 2011 FRIENDSHIP LINK PROTOCOL, LLC Relationship networks having link quality metrics with inference and concomitant digital value exchange
8727978, May 12 2006 Philips North America LLC Health monitoring appliance
8728001, Feb 10 2006 Lawrence A., Lynn Nasal capnographic pressure monitoring system
8729040, May 29 2008 The Board of Trustees of the Leland Stanford Junior University Cell line, system and method for optical control of secondary messengers
8731650, May 03 2002 The Trustees of Columbia University in the City of New York Single Trial detection in encephalography
8731656, Dec 02 2005 Medtronic, Inc. Closed-loop therapy adjustment
8731987, May 07 2007 Schlumberger Technology Corporation Method and apparatus to automatically recover well geometry from low frequency electromagnetic signal measurements
8733290, Apr 03 2012 System for providing an interface for interacting with a laboratory animal
8734356, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8734357, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8734498, Jun 16 2005 Depuy Synthes Products, LLC Intranasal red light probe for treating alzheimer's disease
8738121, Aug 23 2010 Medtronic, Inc Method and apparatus for distinguishing epileptic seizure and neurocardiogenic syncope
8738126, Mar 29 2006 Catholic Healthcare West Synchronization of vagus nerve stimulation with the cardiac cycle of a patient
8738136, Oct 15 2002 Medtronic, Inc. Clustering of recorded patient neurological activity to determine length of a neurological event
8738140, Oct 21 2004 Advanced Neuromodulation Systems, Inc. Stimulation of the amygdalohippocampal complex to treat neurological conditions
8738395, Dec 30 2008 The Invention Science Fund I, LLC Methods and systems for presenting an inhalation experience
8744562, Dec 17 2004 Medtronic, Inc. Method for monitoring or treating nervous system disorders
8744563, Jun 21 2011 SLEEPWELL CO , LTD Mental disorder analysis apparatus, mental disorder analysis method, and program
8747313, May 12 2006 Philips North America LLC Health monitoring appliance
8747336, Oct 16 2005 BT WEARABLES LLC Personal emergency response (PER) system
8747382, Apr 13 2005 University of Maryland, Baltimore; University of Maryland, College Park Techniques for compensating movement of a treatment target in a patient
8750971, Aug 02 2007 Wireless stroke monitoring
8750974, Nov 01 2006 FITLINXX, INC Body worn physiological sensor device having a disposable electrode module
8750992, Feb 28 2005 Cardiac Pacemakers, Inc. Implantable cardiac device with dyspnea measurement
8751008, Aug 09 2011 Boston Scientific Neuromodulation Corporation Remote control data management with correlation of patient condition to stimulation settings and/or with clinical mode providing a mismatch between settings and interface data
8751011, Jul 11 2008 Medtronic, Inc Defining therapy parameter values for posture states
8753296, Feb 05 2004 SANDLEFORD PARK LIMITED, AS SECURITY AGENT Methods and apparatus for rehabilitation and training
8754238, Jul 22 2003 ARENA PHARMACEUTIALS, INC Diaryl and arylheteroaryl urea derivatives as modulators of the 5-HT2A serotonin receptor useful for the prophylaxis and treatment of disorders related thereto
8755854, Jul 31 2009 NELLCOR PURITAN BENNETT IRELAND Methods and apparatus for producing and using lightly filtered photoplethysmograph signals
8755856, Oct 07 1994 JPMorgan Chase Bank, National Association Signal processing apparatus
8755868, Sep 14 2009 IMEC Adaptive sampling
8755869, Apr 29 2011 LivaNova USA, Inc Adjusting neighborhood widths of candidate heart beats according to previous heart beat statistics
8755871, Nov 30 2011 Covidien LP Systems and methods for detecting arrhythmia from a physiological signal
8755877, Mar 12 2012 Texas Instruments Incoporated Real time QRS detection using adaptive threshold
8755901, Jul 11 2008 Medtronic, Inc Patient assignment of therapy parameter to posture state
8756017, Feb 17 2011 YANGTZE UNIVERSITY Method for detecting formation resistivity outside of metal casing using time-domain electromagnetic pulse in well
8758274, Jan 08 2010 Medtronic, Inc. Automated adjustment of posture state definitions for a medical device
8761438, Apr 21 2011 MORPHO DETECTION, LLC Systems and methods for object imaging
8761866, Jul 10 2002 Non-Invasive Technology Inc. Examination and imaging of brain cognitive functions
8761868, Dec 17 2004 Medtronic, Inc. Method for monitoring or treating nervous system disorders
8761869, May 31 2010 Washington University Brain function mapping
8761889, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
8762065, Aug 05 1998 DiLorenzo Biomedical, LLC Closed-loop feedback-driven neuromodulation
8762202, Oct 29 2009 Nielsen Consumer LLC Intracluster content management using neuro-response priming data
8764651, May 24 2006 KONINKLIJKE PHILIPS N V Fitness monitoring
8764652, Mar 08 2007 Nielsen Consumer LLC Method and system for measuring and ranking an “engagement” response to audiovisual or interactive media, products, or activities using physiological signals
8764653, Aug 22 2007 HEART FORCE MEDICAL INC Apparatus for signal detection, processing and communication
8764673, Mar 02 1999 QSC Audio Products, LLC System and method for facilitating group coherence
8768022, Nov 15 2007 Vanderbilt University Apparatus and methods of compensating for organ deformation, registration of internal structures to images, and applications of same
8768427, May 07 2009 SMARTBRAIN AS Electrode fixing device
8768431, Apr 13 2007 The Regents of the University of Michigan Systems and methods for tissue imaging
8768446, Nov 02 2004 Medtronic, Inc. Clustering with combined physiological signals
8768447, Jan 09 2007 General Electric Company Processing of physiological signal data in patient monitoring
8768449, Dec 16 2004 California Institute of Technology Prosthetic devices and methods and systems related thereto
8768471, Oct 24 2008 LivaNova USA, Inc Dynamic cranial nerve stimulation based on brain state determination from cardiac data
8768477, Mar 23 2011 MED-EL Elektromedizinische Geraete GmbH Post-auricular muscle response based hearing prosthesis fitting
8768718, Dec 27 2006 Cardiac Pacemakers, Inc Between-patient comparisons for risk stratification of future heart failure decompensation
8771194, Dec 15 2004 NeuroPace, Inc. Modulation and analysis of cerebral perfusion in epilepsy and other neurological disorders
8774923, Mar 22 2009 Sorin CRM SAS Optimal deep brain stimulation therapy with Q learning
8775340, Dec 19 2008 The Board of Trustees of the University of Illinois Detection and prediction of physiological events in people with sleep disordered breathing using a LAMSTAR neural network
8781193, Nov 18 2008 SYNC-RX, LTD Automatic quantitative vessel analysis
8781197, Apr 28 2008 Cornell University Tool for accurate quantification in molecular MRI
8781557, Aug 11 1999 Osteoplastics, LLC Producing a three dimensional model of an implant
8781563, Mar 06 2006 Keenly Health, LLC Ultra wideband monitoring systems and antennas
8781595, Apr 30 2007 Medtronic, Inc Chopper mixer telemetry circuit
8781597, Aug 05 1998 DiLorenzo Biomedical, LLC Systems for monitoring a patient's neurological disease state
8781796, Oct 25 2007 The Trustees of the University of Pennsylvania Systems and methods for individualized alertness predictions
8784109, Aug 03 2005 Cognitive enhancement
8784322, Jun 20 2006 Samsung Electronics Co., Ltd. Apparatus and method of sensing sleeping condition of user
8785441, Nov 19 2004 Arena Pharmaceuticals, Inc. 3-phenyl-pyrazole derivatives as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
8786624, Jun 02 2009 Cyberonics, Inc Processing for multi-channel signals
8787637, Mar 12 2009 COMMISSARIAT A L ENERGIE ATOMQIUE ET AUX ENERGIES ALTERNATIVES; Assistance Publique - Hopitaux de Paris Method for developing an information prediction device, use thereof, and corresponding storage medium and apparatus
8788030, Feb 03 2010 HRL Laboratories, LLC Systems, methods, and apparatus for neuro-robotic tracking point selection
8788033, Sep 15 2009 Rush University Medical Center Energy-releasing carbon nanotube transponder and method of using same
8788044, Jan 21 2005 Systems and methods for tissue stimulation in medical treatment
8788055, May 07 2007 Medtronic, Inc Multi-location posture sensing
8788057, Dec 21 2007 Greatbatch Ltd. Multiplexer for selection of an MRI compatible bandstop filter placed in series with a particular therapy electrode of an active implantable medical device
8790255, Jul 26 2005 adidas AG Computer interfaces including physiologically guided avatars
8790272, Mar 26 2002 adidas AG Method and system for extracting cardiac parameters from plethysmographic signals
8790297, Mar 18 2009 CORINDUS, INC Remote catheter system with steerable catheter
8792972, Feb 05 2009 ALPHA OMEGA ENGINEERING LTD Real-time methods and systems for mapping a target region in the brain during surgery
8792974, Jan 18 2012 BRAINSCOPE SPV LLC Method and device for multimodal neurological evaluation
8792991, Apr 29 2008 Medtronic, Inc Therapy program modification based on therapy guidelines
8795175, Oct 18 2007 Hitachi, LTD Biological measurement system measuring cerebral blood volume changes to find disease or danger
8798717, Jul 03 2009 Siemens Healthcare GmbH Patient support and/or transport means and magnetic resonance system
8798728, Nov 02 2004 Medtronic, Inc. Techniques for data retention upon detection of an event in an implantable medical device
8798735, Jul 12 2002 BioNova Technologies Inc. Method and apparatus for the estimation of anesthetic depth using wavelet analysis of the electroencephalogram
8798736, Mar 16 2009 NeuroSky, Inc. EEG control of devices using sensory evoked potentials
8798773, Sep 30 2011 MAN & SCIENCE S A Electrode configuration for implantable modulator
8801620, Apr 25 2005 University of Florida Research Foundation, Inc. Method and apparatus for diagnosing respiratory disorders and determining the degree of exacerbations
8805516, Sep 13 2004 Neuronix Ltd. Integrated system and method for treating disease using cognitive training and brain stimulation and computerized magnetic photoelectric stimulator (CMPES)
8805518, May 09 2008 Medtronic, Inc Peripheral nerve field stimulation control
8812126, Nov 28 2005 The Cleveland Clinic Foundation System and method to define target volume for stimulation of the spinal cord and peripheral nerves
8812237, Feb 05 2009 Schlumberger Technology Corporation; Saudi Arabian Oil Company Deep-reading electromagnetic data acquisition method
8812245, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8812246, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
8814923, Mar 31 2011 Valkee Oy Light dispensing apparatus
8815582, Apr 23 2008 The Board of Trustees of the Leland Stanford Junior University Mammalian cell expressing Volvox carteri light-activated ion channel protein (VChR1)
8821376, Mar 12 2007 Devices and methods for performing medical procedures in tree-like luminal structures
8821408, Apr 05 2006 The Regents of the University of California Data mining system for noninvasive intracranial pressure assessment
8821559, Mar 14 2005 DEPUY SYNTHES PRODUCTS, INC Light-based implants for treating Alzheimer's disease
8825149, May 11 2006 Northwestern University; Northwestern Univeristy Systems and methods for measuring complex auditory brainstem response
8825166, Jan 21 2005 Multiple-symptom medical treatment with roving-based neurostimulation
8825167, Mar 20 2008 PROFESSOR DR PETER TASS Device and method for auditory stimulation
8825428, Nov 30 2010 NELLCOR PURITAN BENNETT IRELAND Methods and systems for recalibrating a blood pressure monitor with memory
8827912, Apr 24 2009 LivaNova USA, Inc Methods and systems for detecting epileptic events using NNXX, optionally with nonlinear analysis parameters
8827917, Jun 30 2008 NELLCOR PURITAN BENNETT IRELAND Systems and methods for artifact detection in signals
8829908, Mar 16 2009 Schlumberger Technology Corporation Induction coil impedance modeling using equivalent circuit parameters
8831705, Feb 07 2005 CardioSync, Inc. Devices and method for accelerometer-based characterization of cardiac synchrony and dyssynchrony
8831731, May 15 2008 Boston Scientific Neuromodulation Corporation Clinician programmer system and method for calculating volumes of activation
8831732, Apr 29 2010 Cyberonics, Inc Method, apparatus and system for validating and quantifying cardiac beat data quality
8834392, Jan 08 2010 Medtronic, Inc. Posture state classification for a medical device
8834546, Nov 22 2010 The Board of Trustees of the Leland Stanford Junior University Optogenetic magnetic resonance imaging
8838201, Jun 22 2010 The Johns Hopkins University Atlas-based analysis for image-based anatomic and functional data of organism
8838225, Jan 03 2007 Megin Oy Analysis of multi-channel measurement data using orthogonal virtual channels
8838226, Dec 01 2009 Neuro Wave Systems Inc Multi-channel brain or cortical activity monitoring and method
8838227, Aug 02 2005 BRAINSCOPE SPV LLC Portable automatic brain state assessment apparatus
8838247, Jan 06 2010 EVOKE NEUROSCIENCE, INC Transcranial stimulation device and method based on electrophysiological testing
8843199, Dec 12 2003 Cardiac Pacemakers, Inc. Cardiac response classification using multisite sensing and pacing
8843201, Oct 02 2012 Great Lakes Neurotechnologies Inc Wearable, unsupervised transcranial direct current stimulation (tDCS) device for movement disorder therapy, and method of using
8843210, Mar 20 2009 ElectroCore LLC Non-invasive vagal nerve stimulation to treat disorders
8845545, Sep 25 2007 Uroval, Inc. Probe for measuring a patient's bulbocavernosus muscle reflex
8849390, Dec 29 2008 Cyberonics, Inc Processing for multi-channel signals
8849392, Oct 31 2006 FUNCTIONAL NEUROSCIENCE INC Identifying areas of the brain by examining the neuronal signals
8849407, Jan 04 2008 ADVANCED NEUROREHABILITATION, LLC Non-invasive neuromodulation (NINM) for rehabilitation of brain function
8849409, Oct 24 2008 CYBERONICS, INC.; Flint Hills Scientific, LLC Dynamic cranial nerve stimulation based on brain state determination from cardiac data
8849632, May 15 2008 Boston Scientific Neuromodulation Corporation Clinician programmer system and method for generating interface models and displays of volumes of activation
8849681, Aug 06 2007 HARGROVE, JEFFREY B Apparatus and method for remote assessment and therapy management in medical devices via interface systems
8852073, Jan 17 2012 Headwater R&D Inc; HEADWATERS R & D, INCORPORATED Relaxation inducing sleep mask
8852100, Oct 01 2010 Flint Hills Scientific, LLC Detecting, quantifying, and/or classifying seizures using multimodal data
8852103, Oct 17 2011 BFLY OPERATIONS, INC Transmissive imaging and related apparatus and methods
8855758, Aug 03 2006 Imperial Innovations Limited Apparatus and method for obtaining EEG data
8855773, May 15 2008 Boston Scientific Neuromodulation Corporation Clinician programmer system and method for steering volumes of activation
8855775, Nov 14 2006 Cyberonics, Inc Systems and methods of reducing artifact in neurological stimulation systems
8858440, Jul 14 2008 Arizona Board of Regents For and On Behalf Of Arizona State University Methods and devices for modulating cellular activity using ultrasound
8858449, Oct 15 2008 The Board of Trustees of the Leland Stanford Junior University Systems and methods for monitoring heart function
8861819, Nov 09 2012 Samsung Electronics Co., Ltd. Apparatus and method for correcting artifacts of functional image acquired by magnetic resonance imaging
8862196, May 17 2001 Lawrence A., Lynn System and method for automatic detection of a plurality of SP02 time series pattern types
8862210, Sep 14 2009 IMEC; STICHTING IMEC NEDERLAND Analogue signal processors
8862236, Aug 02 2012 HEALTH RESEARCH, INC Method and device to restore and/or improve nervous system functions by modifying specific nervous system pathways
8862581, Apr 28 2008 Agency for Science Technology and Research Method and system for concentration detection
8864310, May 01 2012 RightEye, LLC Systems and methods for evaluating human eye tracking
8864806, May 28 2010 NUROTONE MEDICAL LTD Optical bundle apparatus and method for optical and/or electrical nerve stimulation of peripheral nerves
8868148, Sep 11 2012 Nellcor Puritan Bennett LLC Methods and systems for qualifying physiological values based on segments of a physiological signal
8868163, Jan 16 2008 Massachusetts Institute of Technology Method and apparatus for predicting patient outcomes from a physiological segmentable patient signal
8868172, Dec 28 2005 DiLorenzo Biomedical, LLC Methods and systems for recommending an appropriate action to a patient for managing epilepsy and other neurological disorders
8868173, Apr 20 2011 Medtronic, Inc. Method and apparatus for assessing neural activation
8868174, Feb 24 2009 HONDA MOTOR CO , LTD ; ADVANCED TELECOMMUNICATIONS RESEARCH INSTITUTE INTERNATIONAL Brain information output apparatus, robot, and brain information output method
8868175, Jul 03 2002 Tel Aviv University Future Technology Development L.P. Apparatus and method for estimating stroke volume of the heart using bio-impedance techniques
8868177, Mar 20 2009 ElectroCore LLC Non-invasive treatment of neurodegenerative diseases
8868189, Mar 20 2008 Greatbatch Ltd. Internally grounded flat through filter with hermetically sealed insulative body with internal ground plates
8868201, Apr 20 2011 Medtronic, Inc. Adaptively configuring the validation timeout of a session key used for securing communication with an implantable medical device
8870737, Sep 24 2008 WAVE NEUROSCIENCE, INC Systems and methods for neuro-EEG synchronization therapy
8871797, Jul 22 2003 Arena Pharmaceuticals, Inc. Diaryl and arylheteroaryl urea derivatives as modulators of the 5-HT2A serotonin receptor useful for the prophylaxis and treatment of disorders related thereto
8872640, Jul 05 2011 JOHNS HOPKINS ARAMCO HEALTHCARE COMPANY Systems, computer medium and computer-implemented methods for monitoring health and ergonomic status of drivers of vehicles
8874205, Mar 20 2009 ElectroCore LLC Device and methods for non-invasive electrical stimulation and their use for vagal nerve stimulation
8874218, Oct 20 2008 LivaNova USA, Inc Neurostimulation with signal duration determined by a cardiac cycle
8874227, Mar 20 2009 ElectroCore LLC Devices and methods for non-invasive capacitive electrical stimulation and their use for vagus nerve stimulation on the neck of a patient
8874439, Mar 01 2006 The Regents of the University of California Systems and methods for blind source signal separation
8880207, Dec 10 2008 UNIVERSITY OF QUEENSLAND, THE Multi-parametric analysis of snore sounds for the community screening of sleep apnea with non-gaussianity index
8880576, Sep 23 2011 NELLCOR PURITAN BENNETT IRELAND Systems and methods for determining respiration information from a photoplethysmograph
8886299, Nov 03 2011 IMEC System and method for the analysis of electrocardiogram signals
8886302, Jul 11 2008 Medtronic, Inc Adjustment of posture-responsive therapy
8888672, Sep 25 2007 WAVE NEUROSCIENCE, INC Systems and methods for neuro-EEG synchronization therapy
8888673, Sep 25 2007 WAVE NEUROSCIENCE, INC Systems and methods for neuro-EEG synchronization therapy
8888702, Oct 01 2010 Flint Hills Scientific, LLC Detecting, quantifying, and/or classifying seizures using multimodal data
8888708, Apr 14 1997 JPMorgan Chase Bank, National Association Signal processing apparatus and method
8888723, Feb 05 2004 SANDLEFORD PARK LIMITED, AS SECURITY AGENT Gait rehabilitation methods and apparatuses
8892207, Apr 20 2011 Medtronic, Inc. Electrical therapy for facilitating inter-area brain synchronization
8893120, Jan 29 2010 SCHWEGMAN, LUNDBERG & WOESSNER, P A Controlled use medical applicaton
8898037, Apr 28 2010 NELLCOR PURITAN BENNETT IRELAND Systems and methods for signal monitoring using Lissajous figures
8900284, Mar 14 2005 DEPUY SYNTHES PRODUCTS, INC Red light implant for treating Parkinson's disease
8902070, Mar 30 2009 Tobii AB Eye closure detection using structured illumination
8903479, Jun 19 2012 Texas Instruments Incorporated Real time QRS duration measurement in electrocardiogram
8903483, Feb 09 2007 NeuroPace, Inc. Devices and methods for monitoring physiological information relating to sleep with an implantable device
8903486, Dec 02 2005 Medtronic, Inc. Closed-loop therapy adjustment
8903494, Nov 26 2012 THYNC GLOBAL, INC Wearable transdermal electrical stimulation devices and methods of using them
8906360, Jul 22 2005 BOARD OF TRUSTEES LELAND STANFORD JUNIOR UNIVERSITY, THE Light-activated cation channel and uses thereof
8907668, Oct 14 2011 MOMENT TECHNOLOGIES, LLC High-resolution scanning prism magnetometry
8909345, Jan 04 2008 Non-invasive neuromodulation (NINM) for rehabilitation of brain function
8910638, May 09 2007 Massachusetts Institute of Technology Methods and apparatus for high-throughput neural screening
8913810, Jul 26 2011 Siemens Medical Solutions USA, Inc Simultaneous reconstruction of emission activity and attenuation coefficient distribution from TOF data, acquired with external shell source
8914100, Jun 14 2010 PANASONIC INTELLECTUAL PROPERTY MANAGEMENT CO , LTD Electroencephalogram measurement system, electroencephalogram measurement method, and program thereof
8914115, Dec 03 2009 Medtronic, Inc. Selecting therapy cycle parameters based on monitored brain signal
8914119, Apr 20 2011 Medtronic, Inc. Electrical brain therapy parameter determination based on a bioelectrical resonance response
8914122, Mar 20 2009 ElectroCore LLC Devices and methods for non-invasive capacitive electrical stimulation and their use for vagus nerve stimulation on the neck of a patient
8915741, Aug 18 2003 Cardiac Pacemakers, Inc. Sleep quality data collection and evaluation
8915871, Feb 05 2004 SANDLEFORD PARK LIMITED, AS SECURITY AGENT Methods and apparatuses for rehabilitation exercise and training
8918162, Apr 17 2007 System and method for using three dimensional infrared imaging to provide psychological profiles of individuals
8918176, Apr 23 2012 Medtronic, Inc.; Medtronic, Inc Assessing cognitive disorders based on non-motor epileptiform bioelectrical brain activity
8918178, Mar 20 2009 ELECTROCORE, INC Non-invasive vagal nerve stimulation to treat disorders
8918183, Aug 09 2011 Boston Scientific Neuromodulation Corporation Systems and methods for stimulation-related volume analysis, creation, and sharing
8921320, Jul 21 2011 Board of Supervisors of Louisiana State University and Agricultural and Mechanical College Targeted osmotic lysis of cancer cells
8922376, Jul 09 2010 Nokia Technologies Oy Controlling a user alert
8922788, Dec 22 2012 Covidien LP Methods and systems for determining a probe-off condition in a medical device
8923958, Feb 04 2011 ANALYTICS FOR LIFE INC System and method for evaluating an electrophysiological signal
8924235, Oct 03 2007 Ottawa Hospital Research Institute Method and apparatus for monitoring physiological parameter variability over time for one or more organs
8926959, Jul 22 2005 The Board of Trustees of the Leland Stanford Junior University System for optical stimulation of target cells
8929991, Oct 19 2005 ADVANCED NEUROMODULATION SYSTEMS, INC Methods for establishing parameters for neural stimulation, including via performance of working memory tasks, and associated kits
8929999, Sep 30 2011 MAN & SCIENCE S A Electrode configuration for implantable modulator
8932218, Feb 19 2009 Methodology, use and benefits of neuroacoustic frequencies for assessing and improving the health and well-being of living organisms
8932227, Jul 28 2000 Lawrence A., Lynn System and method for CO2 and oximetry integration
8932562, Nov 05 2010 The Board of Trustees of the Leland Stanford Junior University Optically controlled CNS dysfunction
8933696, May 20 2011 SPIN SENSING FACTORY CORP Magnetic sensor and biomagnetism measurement system
8934685, Sep 21 2010 General Electric Company System and method for analyzing and visualizing local clinical features
8934965, Jun 03 2011 The Board of Trustees of the University of Illinois Conformable actively multiplexed high-density surface electrode array for brain interfacing
8934967, Jul 02 2008 The Board of Regents, The University of Texas System Systems, methods and devices for treating tinnitus
8934979, Dec 27 2010 Boston Scientific Neuromodulation Corporation Neurostimulation system for selectively estimating volume of activation and providing therapy
8934986, Apr 14 2011 Medtronic, Inc. Implantable medical devices storing graphics processing data
8936629, Apr 12 2006 GEARBOX, LLC Autofluorescent imaging and target ablation
8936630, Nov 25 2009 Medtronic, Inc. Optical stimulation therapy
8938102, Jun 17 2011 QUANTITATIVE IMAGING, INC Methods and apparatus for assessing activity of an organ and uses thereof
8938289, Aug 25 2004 SANDLEFORD PARK LIMITED, AS SECURITY AGENT Motor training with brain plasticity
8938290, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
8938301, Jan 06 2010 EVOKE NEUROSCIENCE, INC Headgear with displaceable sensors for electrophysiology measurement and training
8939903, Jun 17 2010 FORETHOUGHT PTY LTD Measurement of emotional response to sensory stimuli
8942777, Oct 06 1993 JPMorgan Chase Bank, National Association Signal processing apparatus
8942813, Jan 06 2010 Evoke Neuroscience, Inc. Transcranial stimulation device and method based on electrophysiological testing
8942817, Jul 28 2009 GEARBOX, LLC Broadcasting a signal indicative of a disease, disorder, or symptom determined in response to contactlessly acquired information
8945006, Oct 01 2010 Flunt Hills Scientific, LLC Detecting, assessing and managing epilepsy using a multi-variate, metric-based classification analysis
8948834, Oct 06 1993 JPMorgan Chase Bank, National Association Signal processing apparatus
8948849, Apr 28 2008 THE TRUSTEES OF DARTMOUTH COLLEGE System and method for optode and electrode positioning cap for electroencephalography, diffuse optical imaging, and functional neuroimaging
8948855, Sep 16 2010 Flint Hills Scientific, LLC Detecting and validating a detection of a state change from a template of heart rate derivative shape or heart beat wave complex
8948860, Aug 02 2005 BRAINSCOPE SPV LLC Field-deployable concussion detector
8951189, Jun 15 2010 Flint Hills Scientific, LLC Systems approach to comorbidity assessment
8951190, Sep 28 2005 ZIN TECHNOLOGIES, INC Transfer function control for biometric monitoring system
8951192, Jun 15 2010 Flint Hills Scientific, LLC Systems approach to disease state and health assessment
8951203, Apr 22 2009 Cardiac Pacemakers, Inc. Measures of cardiac contractility variability during ischemia
8954139, Aug 25 2010 Angel Medical Systems, Inc. Acute ischemia detection based on parameter value range analysis
8954146, Feb 28 2005 Cardiac Pacemakers, Inc. Implantable cardiac device with dyspnea measurement
8954293, Jul 16 2009 Christian-Albrechts-Universitat zu Kiel Method and arrangement for reconstructing the source of an electromagnetic field
8955010, Jan 21 2009 Nielsen Consumer LLC Methods and apparatus for providing personalized media in video
8955974, May 01 2012 RightEye, LLC Systems and methods for evaluating human eye tracking
8956277, Feb 28 2010 Stimulation method via deep brain stimulation
8956363, Jun 17 2008 The Board of Trustees of the Leland Stanford Junior University Methods, systems and devices for optical stimulation of target cells using an optical transmission element
8958868, Oct 28 2008 NORTH CAROLINA UNIVERSITY, A CONSTITUENT INSTITUTION OF THE UNIVERSITY OF NORTH CAROLINA Systems and methods for multichannel wireless implantable neural recording
8958870, Apr 29 2008 Medtronic, Inc Therapy program modification
8958882, Jan 06 2010 Evoke Neuroscience, Inc. Transcranial stimulation device and method based on electrophysiological testing
8961187, Feb 16 2007 FORSCHUNGSZENTRUM JUELICH GMBH Phantom
8961385, Dec 05 2003 SOFPULSE, INC Devices and method for treatment of degenerative joint diseases with electromagnetic fields
8961386, Sep 25 2007 WAVE NEUROSCIENCE, INC Systems and methods for neuro-EEG synchronization therapy
8962042, Sep 28 2010 Methods for treating neurological disorders using nutrient compositions
8962589, May 29 2008 The Board of Trustees of the Leland Stanford Junior University Cell line, system and method for optical control of secondary messengers
8964298, Feb 28 2010 Microsoft Technology Licensing, LLC Video display modification based on sensor input for a see-through near-to-eye display
8965492, Nov 01 2006 FITLINXX, INC Body worn physiological sensor device having a disposable electrode module
8965513, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
8965514, Apr 13 2009 Research Foundation of the City University of New York Transcranial stimulation
8968172, Apr 02 2011 Biomobie Corporation Handheld cell excitation terminal capable of dynamic optimization of therapeutic effect and remote therapeutic system
8968176, Apr 24 2007 Cornfield Electronics, Inc. Guide glasses
8968195, May 12 2006 KONINKLIJKE PHILIPS N V Health monitoring appliance
8968376, May 28 2010 NUROTONE MEDICAL LTD Nerve-penetrating apparatus and method for optical and/or electrical nerve stimulation of peripheral nerves
8971936, Sep 01 2009 VIVOMETRICS, INC Multimodal method and system for transmitting information about a subject
8972004, Nov 10 2005 Electrocore, LLC Magnetic stimulation devices and methods of therapy
8972013, Oct 28 2005 LivaNova USA, Inc Using physiological sensor data with an implantable medical device
8974365, Nov 25 2012 Treatment of thalamocortical dysrhythmia
8977024, Jan 31 2014 Afraxis, Inc.; AFRAXIS, INC Distributed anatomical image analysis
8977110, Jan 21 2009 Nielsen Consumer LLC Methods and apparatus for providing video with embedded media
8977362, Apr 27 2010 Rhode Island Hospital Peripheral pain management
8980891, Dec 18 2009 ARENA PHARMACEUTICALS, INC Crystalline forms of certain 3-phenyl-pyrazole derivatives as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
8983155, Jul 07 2004 Cleveland Clinic Foundation Method and device for displaying predicted volume of influence with patient-specific atlas of neural tissue
8983591, Oct 15 2010 NOVELA NEUROTECHNOLOGY; HCV INVESTMENTS, LLC Method and apparatus for detecting seizures
8983620, Mar 15 2013 Medtronic, Inc Systems, apparatus and methods facilitating longevity extension for implantable medical devices
8983628, Mar 20 2009 ElectroCore LLC Non-invasive vagal nerve stimulation to treat disorders
8983629, Mar 20 2009 ElectroCore LLC Non-invasive vagal nerve stimulation to treat disorders
8985119, Sep 09 2005 NERVESENSE LTD Method and apparatus for optical stimulation of nerves and other animal tissue
8986207, Nov 12 2009 Covidien LP Systems and methods for providing sensor arrays for detecting physiological characteristics
8989835, Aug 17 2012 Nielsen Consumer LLC Systems and methods to gather and analyze electroencephalographic data
8989836, Mar 08 2013 BRAINSCOPE SPV LLC Electrode array and method of placement
8989863, Mar 23 2009 Flint Hills Scientific, LLC System and apparatus for increasing regularity and/or phase-locking of neuronal activity relating to an epileptic event
8989867, Jul 14 2011 LivaNova USA, Inc Implantable nerve wrap for nerve stimulation configured for far field radiative powering
8989868, Sep 30 2011 MAN & SCIENCE S A Apparatus and method for controlling energy delivery as a function of degree of coupling
8989871, Sep 21 2011 Sorin CRM SAS; SORIN CRM S A S Pacing lead in an extended area of a heart cavity, implantable by over the wire technique in the deep coronary network
8992230, Jan 23 2012 VIRTAMED AG Medical training systems and methods
8993623, Feb 08 2007 MED-LIFE DISCOVERIES LP Method for lowering cholesterol
8996112, Feb 14 2008 Cardiac Pacemakers, Inc. Method and apparatus for phrenic stimulation detection
8996120, Dec 20 2008 Advanced Bionics AG Methods and systems of adjusting one or more perceived attributes of an audio signal
8998828, Jul 09 2009 NIKE, Inc Visualization testing and/or training
9002458, Jun 29 2013 THYNC GLOBAL, INC Transdermal electrical stimulation devices for modifying or inducing cognitive state
9002471, Dec 21 2007 Greatbatch Ltd. Independently actuatable switch for selection of an MRI compatible bandstop filter placed in series with a particular therapy electrode of an active implantable medical device
9002477, Oct 02 2006 EMKinetics, Inc.; EMKINETICS, INC Methods and devices for performing electrical stimulation to treat various conditions
9004687, May 18 2012 NEUROSYNC, INC Eye tracking headset and system for neuropsychological testing including the detection of brain damage
9005102, Oct 02 2006 EMKINETICS, INC Method and apparatus for electrical stimulation therapy
9005126, May 03 2007 University of Washington Ultrasonic tissue displacement/strain imaging of brain function
9005649, Jul 14 2009 Board of Regents, The University of Texas System Methods for making controlled delivery devices having zero order kinetics
9008367, Nov 18 2008 SYNC-RX, LTD. Apparatus and methods for reducing visibility of a periphery of an image stream
9008754, Nov 18 2008 SYNC-RX, LTD Automatic correction and utilization of a vascular roadmap comprising a tool
9008771, Dec 11 2003 Cardiac Pacemakers, Inc. Non-captured intrinsic discrimination in cardiac pacing response classification
9008780, Oct 05 2011 Case Western Reserve University; University of Kansas Methods and associated neural prosthetic devices for bridging brain areas to improve function
9008970, Oct 06 2011 Halliburton Energy Services, Inc. Compensated crosswell tomography methods and systems
9011329, Apr 19 2004 GEARBOX, LLC Lumenally-active device
9014216, Jun 01 2007 The Trustees of Columbia University in the City of New York Real-time time encoding and decoding machines
9014453, Nov 18 2008 SYNC-RX, LTD. Automatic angiogram detection
9014804, Apr 27 2007 Medtronic, Inc. Implantable medical device for treating neurological conditions including ECG sensing
9014811, Jun 29 2013 THYNC GLOBAL, INC Transdermal electrical stimulation methods for modifying or inducing cognitive state
9014819, Sep 18 2003 Cardiac Pacemakers, Inc. Autonomic arousal detection system and method
9014823, Nov 10 2005 Electrocore, LLC Methods and devices for treating primary headache
9015057, Sep 25 2007 WAVE NEUROSCIENCE, INC Systems and methods for controlling and billing neuro-EEG synchronization therapy
9015087, Oct 09 2012 AT&T Intellectual Property I, L.P. Methods, systems, and products for interfacing with neurological and biological networks
9020576, Mar 31 2008 Okayama Prefecture Biological measurement apparatus and biological stimulation apparatus
9020582, Sep 16 2010 Flint Hills Scientific, LLC Detecting or validating a detection of a state change from a template of heart rate derivative shape or heart beat wave complex
9020585, Jun 18 2007 New York University Electronic identity card
9020586, May 13 2011 HONDA MOTOR CO , LTD ; ADVANCED TELECOMMUNICATIONS RESEARCH INSTITUTE INTERNATIONAL Brain activity measuring apparatus, brain activity measuring method, brain activity deducing apparatus, brain activity deducing method, and brain-machine interface apparatus
9020598, Nov 10 2005 Electrocore, LLC Methods and devices for treating primary headache
9020612, Jan 04 2008 Non-invasive neuromodulation (NINM) for rehabilitation of brain function
9020789, Jul 07 2004 The Cleveland Clinic Foundation Systems and methods for determining volume of activation for deep brain stimulation
9022930, Dec 27 2006 Cardiac Pacemakers, Inc Inter-relation between within-patient decompensation detection algorithm and between-patient stratifier to manage HF patients in a more efficient manner
9022936, Oct 17 2011 BFLY OPERATIONS, INC Transmissive imaging and related apparatus and methods
9025845, Jun 17 2011 QUANTITATIVE IMAGING, INC Methods and apparatus for assessing activity of an organ and uses thereof
9026194, Mar 03 2011 MOMENT TECHNOLOGIES, LLC Current diverter for magnetic stimulation of biological systems
9026202, Aug 30 2012 ALIVECOR, INC. Cardiac performance monitoring system for use with mobile communications devices
9026217, May 15 2008 Boston Scientific Neuromodulation Corporation Clinician programmer system and method for steering volumes of activation
9026218, Jun 19 2003 Advanced Neuromodulation Systems, Inc. Method of treating depression, mood disorders and anxiety disorders using neuromodulation
9026372, Nov 21 2007 ACCENTIA BIOPHARMACEUTICALS, INC Methods for providing a system of care for a high-dose oxazaphosphorine drug regimen
9028405, May 16 2006 KONINKLIJKE PHILIPS N V Personal monitoring system
9028412, Oct 17 2011 BFLY OPERATIONS, INC Transmissive imaging and related apparatus and methods
9031644, Aug 25 2010 Angel Medical Systems, Inc. Threshold adjustment schemes for acute ischemia detection
9031653, Jul 26 2012 Nyxoah SA Internal resonance matching between an implanted device and an external device
9031655, Apr 30 1999 Flint Hills Scientific, LLC Vagal nerve stimulation techniques for treatment of epileptic seizures
9031658, Oct 14 2007 Board of Regents, The University of Texas System Wireless neural recording and stimulating system
9033884, Oct 17 2011 BFLY OPERATIONS, INC Transmissive imaging and related apparatus and methods
9034055, Sep 29 2010 University of Pittsburgh - Of the Commonwealth System of Higher Education Human-machine interface based on task-specific temporal postural synergies
9034911, Oct 28 2008 ARENA PHARMACEUTICALS, INC Composition of a 5-HT2A serotonin receptor modulator useful for the treatment of disorders related thereto
9034923, Feb 08 2007 MED-LIFE DISCOVERIES LP Methods for the treatment of senile dementia of the alzheimer's type
9035657, Apr 10 2009 Schlumberger Technology Corporation Electromagnetic logging between a cased borehole and surface
9036844, Nov 10 2013 Hearing devices based on the plasticity of the brain
9037224, Aug 02 2010 Chi Yung, Fu Apparatus for treating a patient
9037225, Jul 13 2007 NeuroWave Systems Inc. Method and system for acquiring biosignals during delivery of anesthesia or sedation in the presence of HF interference
9037254, Aug 31 2005 Methods and systems for semi-automatic adjustment of medical monitoring and treatment
9037256, Sep 01 2011 Boston Scientific Neuromodulation Corporation Methods and system for targeted brain stimulation using electrical parameter maps
9037530, Jun 26 2008 Microsoft Technology Licensing, LLC Wearable electromyography-based human-computer interface
9042074, Apr 16 2010 JAMES T BERAN REVOCABLE TRUST DATED DECEMBER 26, 2002 Varying electrical current and/or conductivity in electrical current channels
9042201, Oct 21 2011 CEREVAST MEDICAL, INC Method and system for direct communication
9042952, May 17 2001 Lawrence A., Lynn; LAWRENCE A LYNN System and method for automatic detection of a plurality of SPO2 time series pattern types
9042958, Nov 29 2005 CLEARPOINT NEURO, INC MRI-guided localization and/or lead placement systems, related methods, devices and computer program products
9042988, Aug 05 1998 DiLorenzo Biomedical, LLC Closed-loop vagus nerve stimulation
9043001, Nov 10 2005 Electrocore, LLC Methods and devices for treating primary headache
9044188, Dec 28 2005 CYBERONICS, INC. Methods and systems for managing epilepsy and other neurological disorders
9044612, Sep 30 2011 MAN & SCIENCE S A Apparatus and method for extending implant life using a dual power scheme
9050469, Nov 26 2003 FLINT HILLS SCIENTIFIC, L L C Method and system for logging quantitative seizure information and assessing efficacy of therapy using cardiac signals
9050470, May 15 2008 Boston Scientific Neuromodulation Corporation Clinician programmer system interface for monitoring patient progress
9050471, Jul 11 2008 Medtronic, Inc Posture state display on medical device user interface
9053516, Jul 15 2013 Risk assessment using portable devices
9053534, Nov 23 2011 The Regents of the University of Michigan Voxel-based approach for disease detection and evolution
9055871, Oct 15 2008 The Board of Trustees of the Leland Stanford Junior University Weighing scale and sensor systems and methods for monitoring heart function
9055974, Apr 14 2011 Medtronic, Inc. Implantable medical devices storing graphics processing data
9056195, Mar 15 2013 LivaNova USA, Inc Optimization of cranial nerve stimulation to treat seizure disorderse during sleep
9058473, Aug 29 2007 International Business Machines Corporation User authentication via evoked potential in electroencephalographic signals
9060671, Aug 17 2012 Nielsen Consumer LLC Systems and methods to gather and analyze electroencephalographic data
9060683, May 12 2006 KONINKLIJKE PHILIPS N V Mobile wireless appliance
9060695, Nov 30 2011 Covidien LP Systems and methods for determining differential pulse transit time from the phase difference of two analog plethysmographs
9060722, Jun 08 2010 VITAL METRIX INC Apparatus for processing physiological sensor data using a physiological model and method of operation therefor
9060746, Nov 30 2011 Covidien LP Systems and methods for detecting arrhythmia from a physiological signal
9061132, Feb 18 2011 Greatbatch Ltd. Positioning of a medical device conductor in an MRI environment to reduce RF induced current
9061133, Dec 27 2012 Brainsonix Corporation Focused ultrasonic transducer navigation system
9061151, Sep 30 2011 MAN & SCIENCE S A Apparatus and method to control an implant
9061153, Apr 20 2011 TYLERTON INTERNATIONAL, INC Method of treating a patient
9063183, Apr 04 2011 COLUMBIA PEAK VENTURES, LLC Magnetic shield, program, and selection method
9063643, Mar 29 2011 Boston Scientific Neuromodulation Corporation System and method for leadwire location
9064036, Apr 24 2008 HARVEST BIO LLC Methods and systems for monitoring bioactive agent use
9067052, Mar 02 2009 YEDA RESEARCH AND DEVELOPMENT CO LTD AT THE WEIZMANN INSTITUTE OF SCIENCE Magnetic configuration and timing scheme for transcranial magnetic stimulation
9067054, Mar 10 2011 Electrocore, LLC Devices and methods for non-invasive capacitive electrical stimulation and their use for vagus nerve stimulation on the neck of a patient
9067070, Mar 12 2013 Medibotics LLC Dysgeusia-inducing neurostimulation for modifying consumption of a selected nutrient type
9069031, Mar 20 2012 The Regents of the University of California Piezoelectrically actuated magnetic-field sensor
9069097, Dec 02 2008 Schlumberger Technology Corporation Surface to borehole electromagnetic surveying using metallic well casings as electrodes
9070492, Sep 14 2010 The General Hospital Corporation Nanoporous metal multiple electrode array and method of making same
9072449, Mar 15 2013 EMTensor GmbH Wearable/man-portable electromagnetic tomographic imaging
9072482, Sep 16 2010 General Electric Company Method and apparatus for automatic seizure monitoring
9072832, Oct 15 2002 Medtronic, Inc. Clustering of recorded patient neurological activity to determine length of a neurological event
9072870, Jan 25 2008 Medtronic, Inc Sleep stage detection
9072905, May 15 2008 Boston Scientific Neuromodulation Corporation Clinician programmer system and method for steering volumes of activation
9074976, Mar 01 2011 IMAGION BIOSYSTEMS, INC Viscosity measuring method
9076212, May 19 2006 The Queen's Medical Center; The University of Hawaii; The Medical College of Wisconsin, Inc.; UWM Research Foundation, Inc. Motion tracking system for real time adaptive imaging and spectroscopy
9078564, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
9078577, Dec 06 2012 Massachusetts Institute of Technology Circuit for heartbeat detection and beat timing extraction
9078584, Apr 21 2010 TOHOKU UNIVERSITY Electroencephalogram electrode unit for small animals and measurement system using the same
9079039, Jul 02 2013 Medtronic INC State machine framework for programming closed-loop algorithms that control the delivery of therapy to a patient by an implantable medical device
9079940, Mar 17 2010 The Board of Trustees of the Leland Stanford Junior University Light-sensitive ion-passing molecules
9081488, Oct 19 2011 Boston Scientific Neuromodulation Corporation Stimulation leadwire and volume of activation control and display interface
9081882, Aug 12 2010 HeartFlow, Inc Method and system for patient-specific modeling of blood flow
9081890, Nov 13 2012 Daegu Gyeongbyk Institute of Science and Technology Rehabilitation training system and method
9082169, Dec 01 2010 Brainlab AG Longitudinal monitoring of pathology
9084584, Jun 10 2011 KONINKLIJKE PHILIPS N V Method and apparatus for selecting differential input leads
9084885, Jun 17 2008 The Board of Trustees of the Leland Stanford Junior University Methods, systems and devices for optical stimulation of target cells using an optical transmission element
9084896, May 15 2008 Boston Scientific Neuromodulation Corporation Clinician programmer system and method for steering volumes of activation
9084900, Jun 29 2012 Boston Scientific Neuromodulation Corporation Neuromodulation system and method for reducing energy requirements using feedback
9087147, Mar 31 2014 HeartFlow, Inc. Systems and methods for determining blood flow characteristics using flow ratio
9089310, Mar 10 2010 BRAINSCOPE SPV LLC Method and device for removing EEG artifacts
9089400, Apr 20 2006 University of Pittsburgh—Of the Commonwealth System of Higher Education Methods, devices and systems for treating insomnia by inducing frontal cerebral hypothermia
9089683, Feb 28 2010 Neuromodulation method via deep-brain stimulation
9089707, Jul 02 2008 The Board of Regents, The University of Texas System Systems, methods and devices for paired plasticity
9089713, Aug 31 2005 Methods and systems for semi-automatic adjustment of medical monitoring and treatment
9089719, Mar 20 2009 ELECTROCORE, INC Non-invasive methods and devices for inducing euphoria in a patient and their therapeutic application
9091785, Jan 08 2013 Halliburton Energy Services, Inc.; HALLIBURTON ENERGY SERVICES, INC HESI Fiberoptic systems and methods for formation monitoring
9092556, Mar 15 2013 EAGLEYEMED, INC Multi-site data sharing platform
9092895, Dec 20 2010 General Electric Company System and method for soft-field reconstruction
9095266, Aug 02 2010 Method for treating a patient
9095268, Dec 22 2006 Natus Medical Incorporated System for sleep stage determination using frontal electrodes
9095295, Sep 01 2006 Board of Regents of the University of Texas Device and method for measuring information processing speed of the brain
9095303, Mar 23 2009 FLINT HILLS SCIENTIFIC, L L C System and apparatus for early detection, prevention, containment or abatement of spread abnormal brain activity
9095314, Jun 13 2008 Flint Hills Scientific, LLC Medical device failure detection and warning system
9095618, May 22 2008 Ramot at Tel-Aviv University Ltd. Conjugates of a polymer, a bisphosphonate and an anti-angiogenesis agent and uses thereof in the treatment and monitoring of bone related diseases
9095713, Dec 21 2004 Boston Scientific Neuromodulation Corporation Methods and systems for treating autism by decreasing neural activity within the brain
9100758, Nov 12 2010 PANASONIC INTELLECTUAL PROPERTY MANAGEMENT CO , LTD Sound pressure assessment system, and method and program thereof
9101263, May 23 2008 The Invention Science Fund I, LLC Acquisition and association of data indicative of an inferred mental state of an authoring user
9101276, Jul 06 2006 Regents of the University of Minnesota Analysis of brain patterns using temporal measures
9101279, Feb 15 2006 VIRTUAL VIDEO REALITY BY RITCHEY, LIMITED LIABILITY CORPORATION Mobile user borne brain activity data and surrounding environment data correlation system
9101690, Jul 22 2005 The Board of Trustees of the Leland Stanford Junior University Light-activated cation channel and uses thereof
9101759, Jul 08 2008 The Board of Trustees of the Leland Stanford Junior University Materials and approaches for optical stimulation of the peripheral nervous system
9101766, Oct 16 2009 The Board of Trustees of the Leland Stanford Junior University Eliciting analgesia by transcranial electrical stimulation
9102717, Mar 01 2010 THE J DAVID GLADSTONE INSTITUTES Antibody specific for apolipoprotein and methods of use thereof
9107586, May 24 2006 KONINKLIJKE PHILIPS N V Fitness monitoring
9107595, Sep 29 2014 The United States of America as represented by the Secretary of the Army; ARMY, UNITED STATES OF AMERICA AS REPRESENTED BY THE SECRETARY OF THE, THE Node excitation driving function measures for cerebral cortex network analysis of electroencephalograms
9108041, Mar 29 2006 DIGNITY HEALTH Microburst electrical stimulation of cranial nerves for the treatment of medical conditions
9113777, Mar 26 2013 JHANJI, NEERAJ Ultra low power platform for remote health monitoring
9113801, Aug 05 1998 DiLorenzo Biomedical, LLC Methods and systems for continuous EEG monitoring
9113803, Jul 13 2011 Sumitomo Heavy Industries, Ltd. Magnetoencephalography meter for measuring neuromagnetism
9113830, May 31 2011 NELLCOR PURITAN BENNETT IRELAND Systems and methods for detecting and monitoring arrhythmias using the PPG
9116201, Jan 30 2014 QUSPIN INC Method for detecting zero-field resonance
9116835, Sep 29 2014 The United States of America as represented by the Secretary of the Army; UNITED STATES OF AMERICA AS REPRESENTED BY THE SECRETARY OF THE ARMY, THE Method and apparatus for estimating cerebral cortical source activations from electroencephalograms
9118775, Aug 24 2010 LG Electronics Inc. Mobile terminal and method of controlling operation of the mobile terminal
9119533, Oct 07 2008 MEDIDATA SOLUTIONS, INC Systems, methods, and devices having stretchable integrated circuitry for sensing and delivering therapy
9119551, Nov 08 2010 TELEFLEX LIFE SCIENCES LLC Endovascular navigation system and method
9119583, Jul 29 2002 Forschungzentrum Julich GmbH Method for modulation of neuronal activity in the brain by means of sensory stimulation and detection of brain activity
9119597, Sep 23 2011 NELLCOR PURITAN BENNETT IRELAND Systems and methods for determining respiration information from a photoplethysmograph
9119598, Sep 11 2012 Covidien LP Methods and systems for determining physiological information using reference waveforms
9121964, Jan 13 2012 WESTERNGECO L L C Parameterizing a geological subsurface feature
9125574, Sep 22 2006 Rutgers, The State University System and method for acoustic detection of coronary artery disease and automated editing of heart sound data
9125581, May 23 2012 COLUMBIA PEAK VENTURES, LLC Continuous modeling for dipole localization from 2D MCG images with unknown depth
9125788, Jun 02 2009 Agency for Science Technology and Research System and method for motor learning
9126050, Mar 20 2009 ELECTROCORE, INC Non-invasive vagus nerve stimulation devices and methods to treat or avert atrial fibrillation
9131864, Feb 04 2011 8825319 CANADA LIMITED System and method for evaluating an electrophysiological signal
9133024, Sep 03 2003 LIFE PATCH INTERNATIONAL, INC Personal diagnostic devices including related methods and systems
9133709, Nov 17 2009 Board of Regents, The University of Texas System Determination of oil saturation in reservoir rock using paramagnetic nanoparticles and magnetic field
9135221, May 25 2006 ELMINDA LTD. Neuropsychological spatiotemporal pattern recognition
9135400, Jul 07 2004 The Cleveland Clinic Foundation Method and system for displaying a volume of influence by an electrode inserted in neural tissue
9138156, May 31 2012 Seiko Epson Corporation 2D dipole localization using absolute value of MCG measurements
9138175, May 19 2006 The Queen's Medical Center; The University of Hawaii; The Medical College of Wisconsin, Inc.; UWM Research Foundation, Inc. Motion tracking system for real time adaptive imaging and spectroscopy
9138183, Feb 03 2010 Covidien LP Combined physiological sensor systems and methods
9138579, Aug 02 2012 Health Research, Inc. Method and device to restore and/or improve nervous system functions by modifying specific nervous system pathways
9138580, Oct 30 2007 Synapse Biomedical, Inc. Device and method of neuromodulation to effect a functionally restorative adaption of the neuromuscular system
9142145, Jan 23 2012 VIRTAMED AG Medical training systems and methods
9142185, Aug 30 2012 WEST TEXAS TECHNOLOGY PARTNERS, LLC Method and apparatus for selectively presenting content
9144392, Aug 25 2006 Aurum Biosciences Limited Method of imaging metabolic function
9149195, Apr 21 2006 Welch Allyn, Inc Methods and apparatus for quantifying the risk of cardiac death using exercise induced heart rate recovery metrics
9149197, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
9149210, Jan 08 2010 Medtronic, Inc. Automated calibration of posture state classification for a medical device
9149214, Nov 24 2010 PANASONIC INTELLECTUAL PROPERTY MANAGEMENT CO , LTD Annoyance judgment system, apparatus, method, and program
9149226, Apr 01 2003 Sunstar Suisse SA Method of and apparatus for monitoring of muscle activity
9149255, Oct 17 2011 BFLY OPERATIONS, INC Image-guided high intensity focused ultrasound and related apparatus and methods
9149577, Dec 15 2008 OTSUKA PHARMACEUTICAL CO , LTD Body-associated receiver and method
9149599, Apr 09 2008 Lotus Magnus, LLC Brain stimulation systems and methods
9149719, Dec 19 2008 Agency for Science, Technology and Research; National University of Singapore; INSTITUTE OF MENTAL HEALTH Device and method for generating a representation of a subject's attention level
9152757, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
9155373, Aug 02 2004 VENTRK, LLC Medical overlay mirror
9155484, Nov 01 2006 FITLINXX, INC Body worn physiological sensor device having a disposable electrode module
9155487, Oct 27 2008 NORCONNECT INC Method and apparatus for biometric analysis using EEG and EMG signals
9155521, Oct 17 2011 BFLY OPERATIONS, INC Transmissive imaging and related apparatus and methods
9161715, May 23 2008 The Invention Science Fund I, LLC Determination of extent of congruity between observation of authoring user and observation of receiving user
9162051, Sep 21 2006 NeuroPace, Inc Treatment of language, behavior and social disorders
9162052, Sep 21 2006 NeuroPace, Inc. Treatment of language, behavior and social disorders
9165472, Jan 06 2010 EVOKE NEUROSCIENCE, INC Electrophysiology measurement and training and remote databased and data analysis measurement method and system
9167970, Oct 29 2009 The Board of Trustees of the University of Illinois Non-invasive optical imaging for measuring pulse and arterial elasticity in the brain
9167974, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
9167976, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
9167977, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
9167978, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
9167979, Apr 13 2007 UNIVERSITY OF FLORIDA RESEARCH FOUNDATION, INC Atomic magnetometer sensor array magnetic resonance imaging systems and methods
9171353, Jul 16 2008 Siemens Medical Solutions USA, Inc Multimodal image reconstruction with zonal smoothing
9171366, Mar 13 2013 Siemens Medical Solutions USA, Inc Method for localization of an epileptic focus in neuroimaging
9173582, Apr 24 2009 OPTIOS, INC Adaptive performance trainer
9173609, Apr 20 2011 Medtronic, Inc. Brain condition monitoring based on co-activation of neural networks
9173610, Aug 22 2003 Natus Medical Incorporated EEG seizure analysis
9174045, Mar 20 2009 ElectroCore LLC Non-invasive electrical and magnetic nerve stimulators used to treat overactive bladder and urinary incontinence
9174055, Jan 08 2010 Medtronic, Inc. Display of detected patient posture state
9174066, Mar 20 2009 ElectroCore LLC Devices and methods for non-invasive capacitive electrical stimulation and their use for vagus nerve stimulation on the neck of a patient
9175095, Nov 05 2010 The Board of Trustees of the Leland Stanford Junior University Light-activated chimeric opsins and methods of using the same
9177379, Dec 14 2011 ATTI International Services Company, Inc. Method and system for identifying anomalies in medical images
9177416, Mar 22 2010 Microsoft Technology Licensing, LLC Space skipping for multi-dimensional image rendering
9179850, Oct 30 2007 NeuroPace, Inc Systems, methods and devices for a skull/brain interface
9179854, May 16 2005 Three-dimensional localization, display, recording, and analysis of electrical activity in the cerebral cortex
9179855, Nov 01 2010 BRIGHT CLOUD INTERNATIONAL CORP System and method for pain reduction
9179858, Mar 05 2008 New York University Computer-accessible medium, system and method for assessing effect of a stimulus using intersubject correlation
9179875, Dec 21 2009 Insertion of medical devices through non-orthogonal and orthogonal trajectories within the cranium and methods of using
9179876, Apr 30 2012 Covidien LP Systems and methods for identifying portions of a physiological signal usable for determining physiological information
9183351, Sep 19 2010 Mobile system with network-distributed data processing for biomedical applications
9186060, Oct 07 2008 MEDIDATA SOLUTIONS, INC Systems, methods and devices having stretchable integrated circuitry for sensing and delivering therapy
9186106, Apr 29 2011 Flint Hills Scientific, LLC Detecting, quantifying, and/or classifying seizures using multimodal data
9186503, Dec 22 2006 MED-EL Elektromedizinische Geraete GmbH; Cornell University Adaptive airway treatment of dorsal displacement disorders in horses
9186510, Jul 15 2004 Advanced Neuromodulation Systems, Inc. Systems and methods for enhancing or affecting neural stimulation efficiency and/or efficacy
9187745, Jan 10 2007 The Board of Trustees of the Leland Stanford Junior University System for optical stimulation of target cells
9192300, May 23 2008 The Invention Science Fund I, LLC Acquisition and particular association of data indicative of an inferred mental state of an authoring user
9192309, Aug 25 2010 Angel Medical Systems, Inc. Acute ischemia detection based on smoothed temporal thresholding
9198563, Apr 12 2006 GEARBOX, LLC Temporal control of a lumen traveling device in a body tube tree
9198612, Jul 08 2008 International Business Machines Corporation Determination of neuropsychiatric therapy mechanisms of action
9198621, Jun 18 2007 University of Pittsburgh - Of the Commonwealth System of Higher Education Method, apparatus and system for food intake and physical activity assessment
9198624, Jul 06 2010 FUJIFILM Healthcare Corporation Biological photometric device and biological photometry method using same
9198637, Oct 17 2011 BFLY OPERATIONS, INC Transmissive imaging and related apparatus and methods
9198707, Mar 15 2013 Warsaw Orthopedic, Inc Nerve and soft tissue ablation device and method
9198733, Apr 29 2008 Virginia Tech Intellectual Properties, Inc Treatment planning for electroporation-based therapies
9204796, Jun 30 2006 BT WEARABLES LLC Personal emergency response (PER) system
9204835, May 28 2008 The Trustees of Columbia University in the City of New York Voxel-based methods for assessing subjects using positron emission tomography
9204838, Oct 01 2010 Flint Hills Scientific, LLC Detecting, assessing and managing epilepsy using a multi-variate, metric-based classification analysis
9204998, Jul 02 2008 Board of Regents, The University of Texas System Methods, systems, and devices for treating tinnitus with VNS pairing
9208430, Dec 13 2011 SIMIGENCE, INC Computer-implemented simulated intelligence capabilities by neuroanatomically-based system architecture
9208557, Oct 11 2010 Olea Medical System and process for estimating a quantity of interest of a dynamic artery/tissue/vein system
9208558, Aug 11 1999 Osteoplastics, LLC Methods and systems for producing an implant
9211076, Jun 17 2013 Samsung Electronics Co., Ltd. Method and device to measure biosignal
9211077, Dec 13 2007 The Invention Science Fund I, LLC Methods and systems for specifying an avatar
9211212, Apr 20 2006 University of Pittsburgh - Of the Commonwealth System of Higher Education Apparatus and method for modulating sleep
9211411, Aug 26 2010 Medtronic, Inc. Therapy for rapid eye movement behavior disorder (RBD)
9211417, Sep 10 2012 Great Lakes Neurotechnologies Inc Movement disorder therapy system, devices and methods, and intelligent methods of tuning
9213074, Apr 14 2009 The General Hospital Corporation Stem and method for acquiring MRI data from bone and soft tissues
9213076, Feb 27 2012 MedImageMetric LLC System, process and computer-accessible medium for providing quantitative susceptibility mapping
9215298, May 28 2008 Cornell University Patient controlled brain repair system and method of use
9215978, Aug 17 2012 Nielsen Consumer LLC Systems and methods to gather and analyze electroencephalographic data
9220910, Jul 30 2010 LivaNova USA, Inc Seizure detection using coordinate data
9220917, Apr 12 2006 GEARBOX, LLC Systems for autofluorescent imaging and target ablation
9221755, May 18 2006 Arena Pharmaceuticals, Inc. Ethers, secondary amines and derivatives thereof as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
9226672, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
9227056, Oct 02 2012 Great Lakes Neurotechnologies Inc Wearable, unsupervised transcranial direct current stimulation (tDCS) device for movement disorder therapy, and method of using
9229080, Oct 25 2012 NATIONAL TAIWAN UNIVERSITY Method for reconstructing images of a multi-channel MRI system
9230065, Sep 01 2010 National Institute of Advanced Industrial Science and Technology Intention conveyance support device and method
9230539, Jan 06 2009 Regents of the University of Minnesota Automatic measurement of speech fluency
9232910, Nov 17 2008 University Health Network Method and apparatus for monitoring breathing cycle by frequency analysis of an acoustic data stream
9232984, Apr 07 1999 Intuitive Surgical Operations, Inc. Real-time generation of three-dimensional ultrasound image using a two-dimensional ultrasound transducer in a robotic system
9233244, Jun 29 2013 THYNC GLOBAL, INC Transdermal electrical stimulation devices for modifying or inducing cognitive state
9233245, Feb 20 2004 BRAINSGATE LTD SPG stimulation
9233246, Nov 10 2005 Electrocore, LLC Methods and devices for treating primary headache
9233258, Nov 10 2005 Electrocore, LLC Magnetic stimulation devices and methods of therapy
9235679, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
9235685, Jul 07 2004 The Cleveland Clinic Foundation Brain stimulation models, systems, devices, and methods
9238142, Sep 10 2012 Great Lakes NeuroTechnologies Inc.; Great Lakes Neurotechnologies Inc Movement disorder therapy system and methods of tuning remotely, intelligently and/or automatically
9238150, Jul 22 2005 The Board of Trustees of the Leland Stanford Junior University Optical tissue interface method and apparatus for stimulating cells
9241647, Apr 29 2010 LivaNova USA, Inc Algorithm for detecting a seizure from cardiac data
9241665, Nov 14 2012 Methods and systems for quantitative measurement of mental states
9242067, Mar 15 2013 The Regents of the University of Michigan Personalized auditory-somatosensory stimulation to treat tinnitus
9242092, Mar 10 2011 Electrocore, LLC Devices and methods for non-invasive capacitive electrical stimulation and their use for vagus nerve stimulation on the neck of a patient
9247890, Oct 31 2011 Case Western Reserve University Expert system to facilitate source localization of brain electrical activity
9247911, Jul 10 2013 ALIVECOR, INC Devices and methods for real-time denoising of electrocardiograms
9247924, Oct 17 2011 BFLY OPERATIONS, INC Transmissive imaging and related apparatus and methods
9248003, Dec 31 2003 Varian Medical Systems, Inc Receiver used in marker localization sensing system and tunable to marker frequency
9248280, Nov 02 2007 Boston Scientific Neuromodulation Corporation Closed-loop feedback for steering stimulation energy within tissue
9248286, Mar 20 2009 Electrocore, LLC Medical self-treatment using non-invasive vagus nerve stimulation
9248288, Sep 26 2007 Medtronic, Inc. Patient directed therapy control
9248290, Oct 20 2009 MAN & SCIENCE S A Apparatus and methods for feedback-based nerve modulation
9248291, Sep 30 2011 MAN & SCIENCE S A Hypertension therapy implant apparatus
9248296, Aug 28 2012 Boston Scientific Neuromodulation Corporation Point-and-click programming for deep brain stimulation using real-time monopolar review trendlines
9249200, Apr 23 2008 The Board of Trustees of the Leland Stanford Junior University Expression vector comprising a nucleotide sequence encoding a Volvox carteri light-activated ion channel protein (VChR1) and implantable device thereof
9249234, Mar 17 2010 The Board of Trustees of the Leland Stanford Junior University Light-sensitive ion-passing molecules
9251566, Mar 04 2014 Method and system for high-resolution transforms of frequency-space and inverse frequency-space data
9254097, Sep 19 2011 Triad National Security, LLC System and method for magnetic current density imaging at ultra low magnetic fields
9254099, May 23 2013 Medibotics LLC Smart watch and food-imaging member for monitoring food consumption
9254383, Mar 20 2009 Electrocore, LLC Devices and methods for monitoring non-invasive vagus nerve stimulation
9254387, Aug 09 2011 Boston Scientific Neuromodulation Corporation VOA generation system and method using a fiber specific analysis
9256982, Mar 17 2010 Microsoft Technology Licensing, LLC Medical image rendering
9259177, Nov 02 2004 Medtronic, Inc. Techniques for data retention upon detection of an event in an implantable medical device
9259482, May 22 2008 Ramot at Tel-Aviv University Ltd.; Fundacion de la Comunidad Valenciana Centro de Investigacion Principe Felipe Conjugates of polymers having a therapeutically active agent and an angiogenesis targeting moiety attached thereto and uses thereof in the treatment of angiogenesis related diseases
9259591, Dec 28 2007 Cyberonics, Inc Housing for an implantable medical device
9261573, Nov 24 2009 THE JOHNSON REVOCABLE TRUST DATED 6 25 2003 Magnetic resonance system and method employing a digital SQUID
9265458, Dec 04 2012 NEUROSYNC, INC Application of smooth pursuit cognitive testing paradigms to clinical drug development
9265660, Jul 02 2008 Board of Regents, The University of Texas System Methods, systems, and devices for treating tinnitus with VNS pairing
9265661, Jul 02 2008 Board of Regents, The University of Texas System Methods, systems, and devices for treating tinnitus with VNS pairing
9265662, Jul 02 2008 Board of Regents, The University of Texas System Methods, systems, and devices for treating tinnitus with VNS pairing
9265663, Jul 02 2008 Board of Regents, The University of Texas System Methods, systems, and devices for treating tinnitus with VNS pairing
9265931, Sep 21 2006 NeuroPace, Inc. Treatment of language, behavior and social disorders
9265943, Sep 13 2013 YBRAIN INC Method for stimulating living body more accurately and apparatus using the same
9265946, Sep 21 2006 NeuroPace, Inc. Treatment of language, behavior and social disorders
9265965, Sep 30 2011 Board of Regents, The University of Texas System Apparatus and method for delivery of transcranial magnetic stimulation using biological feedback to a robotic arm
9265974, Mar 05 2014 Korea Institute of Science and Technology Apparatus, method, and computer-readable recording medium for generating tactile sensation through non-invasive brain stimulation using ultrasonic waves
9268014, Oct 17 2011 BFLY OPERATIONS, INC Transmissive imaging and related apparatus and methods
9268015, Oct 17 2011 BFLY OPERATIONS, INC Image-guided high intensity focused ultrasound and related apparatus and methods
9268902, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
9271651, Nov 30 2009 General Electric Company System and method for integrated quantifiable detection, diagnosis and monitoring of disease using patient related time trend data
9271657, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
9271660, Jul 02 2010 Virtual prosthetic limb system
9271674, Nov 22 2010 The Board of Trustees of the Leland Stanford Junior University Optogenetic magnetic resonance imaging
9271679, Jul 24 2013 Samsung Electronics Co., Ltd.; Korea University Research and Business Foundation Method and apparatus for processing medical image signal
9272091, Jul 11 2008 Medtronic, Inc. Posture state display on medical device user interface
9272139, Jul 01 2010 Universal closed-loop electrical stimulation system
9272145, Jul 02 2008 The Board of Regents, The University of Texas System Timing control for paired plasticity
9272153, May 15 2008 Boston Scientific Neuromodulation Corporation VOA generation system and method using a fiber specific analysis
9273035, Jul 22 2003 Arena Pharmaceuticals, Inc. Diaryl and arylheteroaryl urea derivatives as modulators of the 5-HT2A serotonin receptor useful for the prophylaxis and treatment of disorders related thereto
9275191, Aug 11 1999 Osteoplastics, LLC Methods and systems for producing an implant
9275451, Dec 20 2006 Spectrum Dynamics Medical Limited Method, a system, and an apparatus for using and processing multidimensional data
9277871, Nov 18 2003 adidas AG Method and system for processing data from ambulatory physiological monitoring
9277873, Oct 03 2012 The Johns Hopkins University Computatonal tool for pre-surgical evaluation of patients with medically refractory epilepsy
9278159, Jul 22 2005 BOARD OF TRUSTEES LELAND STANFORD JUNIOR UNIVERSITY THE Light-activated cation channel and uses thereof
9278231, Jan 30 2009 VASISHTA, VISHWANATH GOPALAKRISHNA Sequentially programmed magnetic field therapeutic system (SPMF)
9280784, Jan 23 2014 THINKALIKE LABORATORIES LLC Method for measuring engagement
9282927, Apr 24 2008 HARVEST BIO LLC Methods and systems for modifying bioactive agent use
9282930, Mar 08 2013 BRAINSCOPE SPV LLC Electrode array and method of placement
9282934, Sep 21 2010 Cortical Dynamics Limited Composite brain function monitoring and display system
9283279, May 11 2011 UNIVERSITA DEGLI STUDI DI PADOVA Targeted polymeric conjugates and uses thereof
9283394, Jun 20 2002 Boston Scientific Neuromodulation Corporation Implantable microstimulators and methods for unidirectional propagation of action potentials
9284353, Mar 01 2007 The Board of Trustees of the Leland Stanford Junior University Mammalian codon optimized nucleotide sequence that encodes a variant opsin polypeptide derived from Natromonas pharaonis (NpHR)
9285249, Oct 04 2012 Honeywell International Inc.; Honeywell International Inc Atomic sensor physics package with metal frame
9289143, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
9289595, Jan 09 2009 CYBERONICS, INC. Medical lead termination sleeve for implantable medical devices
9289599, Mar 29 2006 DIGNITY HEALTH Vagus nerve stimulation method
9289603, Sep 10 2012 Great Lakes Neuro Technologies Inc.; Great Lakes Neurotechnologies Inc Movement disorder therapy system, devices and methods, and methods of remotely tuning
9289609, Dec 27 2010 Boston Scientific Neuromodulation Corporation Neurostimulation system for selectively estimating volume of activation and providing therapy
9292471, Feb 18 2011 HONDA MOTOR CO , LTD Coordinated vehicle response system and method for driver behavior
9292858, Feb 27 2012 Nielsen Consumer LLC Data collection system for aggregating biologically based measures in asynchronous geographically distributed public environments
9292920, Aug 11 1999 Osteoplastics, LLC Methods and systems for producing an implant
9295838, Oct 31 2012 The Regents of the University of California; U S GOVERNMENT - DEPARTMENT OF VETERANS AFFAIRS Methods and systems for treating neurological movement disorders
9296382, Feb 18 2011 HONDA MOTOR CO , LTD System and method for responding to driver behavior
9302069, Mar 05 2008 FORSCHUNGSZENTRUM JUELICH GMBH Device and method for visual stimulation
9302093, Sep 30 2011 Nyxoah SA Devices and methods for delivering energy as a function of condition severity
9302103, Sep 10 2010 Cornell University Neurological prosthesis
9302109, Apr 25 2014 LivaNova USA, Inc Cranial nerve stimulation to treat depression during sleep
9302110, May 15 2008 Boston Scientific Neuromodulation Corporation Clinician programmer system and method for steering volumes of activation
9302114, Sep 15 2009 Rush University Medical Center Energy-releasing carbon nanotube transponder and method of using same
9302116, Apr 21 2009 Duke University; IMMUNOLIGHT, LLC Non-invasive energy upconversion methods and systems for in-situ photobiomodulation
9305376, Nov 09 2012 Samsung Electronics Co., Ltd. Magnetic resonance imaging apparatus and method of acquiring functional image
9307925, Jun 16 2005 Aaken Laboratories Methods and systems for generating electrical property maps of biological structures
9307944, May 28 2008 ORIDION MEDICAL 1987 LTD Medical system, apparatus and method
9308372, May 15 2008 Boston Scientific Neuromodulation Corporation Clinician programmer system and method for generating interface models and displays of volumes of activation
9308392, Jul 08 2008 The Board of Trustees of the Leland Stanford Junior University Materials and approaches for optical stimulation of the peripheral nervous system
9309296, Nov 14 2008 The Board of Trustees of the Leland Stanford Junior University Optically-based stimulation of target cells and modifications thereto
9310985, May 15 2008 Boston Scientific Neuromodulation Corporation System and method for determining target stimulation volumes
9311335, Mar 12 2008 Medtronic Navigation, Inc. Diffusion tensor imaging confidence analysis
9314190, May 11 2006 Great Lakes Neurotechnologies Inc Movement disorder recovery system and method
9314613, Sep 30 2011 MAN & SCIENCE S A Apparatus and methods for modulating nerves using parallel electric fields
9314633, Jan 25 2008 LivaNova USA, Inc Contingent cardio-protection for epilepsy patients
9314635, Dec 24 2003 Cardiac Pacemakers, Inc. Automatic baroreflex modulation responsive to adverse event
9320449, Sep 20 2012 KONICA MINOLTA LABORATORY U S A , INC Method and system for on-line decision making support
9320450, Mar 14 2013 Nielsen Consumer LLC Methods and apparatus to gather and analyze electroencephalographic data
9320451, Feb 27 2014 Kimberly-Clark Worldwide, Inc Methods for assessing health conditions using single coil magnetic induction tomography imaging
9320900, Aug 05 1998 DiLorenzo Biomedical, LLC Methods and systems for determining subject-specific parameters for a neuromodulation therapy
9320913, Apr 16 2014 SOFPULSE, INC Two-part pulsed electromagnetic field applicator for application of therapeutic energy
9320914, Mar 03 2008 DEPUY SYNTHES PRODUCTS, INC Endoscopic delivery of red/NIR light to the subventricular zone
9322895, Sep 04 2009 Aurum Biosciences Limited Method of determining metabolic function using magnetic resonance spectroscopic imaging
9326705, Sep 01 2009 VIVOMETRICS, INC Method and system for monitoring physiological and athletic performance characteristics of a subject
9326720, Feb 09 2011 The Charles Stark Draper Laboratory, Inc Wireless, implantable electro-encephalography system
9326742, Jan 01 2007 Bayer HealthCare LLC Systems for integrated radiopharmaceutical generation, preparation, transportation and administration
9327069, Dec 21 2004 Boston Scientific Neuromodulation Corporation Methods and systems for treating a medical condition by promoting neural remodeling within the brain
9327070, Apr 30 2009 Medtronic, Inc Medical device therapy based on posture and timing
9328107, May 18 2006 Arena Pharmaceuticals, Inc. Primary amines and derivatives thereof as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
9329758, Aug 13 2009 International Business Machines Corporation Multiple sensory channel approach for translating human emotions in a computing environment
9330206, Aug 11 1999 Osteoplastics, LLC Producing a three dimensional model of an implant
9330523, Feb 28 2005 LNW GAMING, INC Wagering game machine with biofeedback-aware game presentation
9331841, May 21 2013 BIOMAGNETIK PARK HOLDING GMBH Data synchronization apparatus
9332939, Oct 01 2010 Detecting, quantifying, and/or classifying seizures using multimodal data
9333334, May 25 2014 THYNC GLOBAL, INC Methods for attaching and wearing a neurostimulator
9333347, Aug 19 2010 Electrocore, LLC Devices and methods for non-invasive electrical stimulation and their use for vagal nerve stimulation on the neck of a patient
9333350, Apr 18 2008 Medtronic, Inc Psychiatric disorder therapy control
9336302, Jul 20 2012 Ool LLC Insight and algorithmic clustering for automated synthesis
9336535, May 12 2010 Nielsen Consumer LLC Neuro-response data synchronization
9336611, Sep 14 2010 Massachusetts Institute of Technology Multi-contrast image reconstruction with joint bayesian compressed sensing
9339200, Mar 31 2014 HeartFlow, Inc. Systems and methods for determining blood flow characteristics using flow ratio
9339227, Jun 22 2010 National Research Council of Canada Cognitive function assessment in a patient
9339641, Oct 02 2006 EMKINETICS, INC Method and apparatus for transdermal stimulation over the palmar and plantar surfaces
9339654, Jul 02 2008 The Board of Regents, The University of Texas System Timing control for paired plasticity
9340589, Nov 05 2010 The Board of Trustees of the Leland Stanford Junior University Light-activated chimeric opsins and methods of using the same
9345412, Nov 25 2009 Leidos, Inc System and method for multiclass discrimination of neural response data
9345609, Jan 11 2013 Elwha LLC Position sensing active torso support
9345886, Jul 02 2008 The Board of Regents, The University of Texas System Timing control for paired plasticity
9345901, May 19 2009 The Trustees of Columbia University in the City of New York Systems and methods for inducing electric field pulses in a body organ
9348974, Oct 24 2007 Medtronic, Inc Remote management of therapy programming
9349178, Nov 24 2014 SIEMENS HEALTHINEERS AG Synthetic data-driven hemodynamic determination in medical imaging
9351640, Jun 30 2006 BT WEARABLES LLC Personal emergency response (PER) system
9351651, Jan 21 2013 COLUMBIA PEAK VENTURES, LLC Magnetic field measurement apparatus
9352145, Dec 22 2004 Boston Scientific Neuromodulation Corporation Methods and systems for treating a psychotic disorder
9352152, Dec 22 2006 CORNELL CENTER FOR TECHNOLOGY, ENTERPRISE & COMMERCIALIZATION CCTEC ; Cornell University Equine airway disorders
9352156, Dec 28 2009 Boston Scientific Neurmodulation Corporation Automatic evaluation technique for deep brain stimulation programming
9357240, Jan 21 2009 Nielsen Consumer LLC Methods and apparatus for providing alternate media for video decoders
9357298, May 02 2013 Sony Corporation Sound signal processing apparatus, sound signal processing method, and program
9357941, Jun 15 2009 CERORA, INC Brain-computer interface test battery for the physiological assessment of nervous system health
9357949, Jan 08 2010 Medtronic, Inc. User interface that displays medical therapy and posture data
9357970, Dec 30 2011 University of Cincinnati Apparatuses and methods for neurological status evaluation using electromagnetic signals
9358361, Apr 24 2008 HARVEST BIO LLC Methods and systems for presenting a combination treatment
9358381, Mar 10 2011 Electrocore, LLC Non-invasive vagal nerve stimulation to treat disorders
9358392, Sep 30 2011 MAN & SCIENCE S A Electrode configuration for implantable modulator
9358393, Nov 09 2004 Stimulation methods and systems for treating an auditory dysfunction
9358398, May 27 2011 Boston Scientific Neuromodulation Corporation Collection of clinical data for graphical representation and analysis
9359449, Mar 17 2010 The Board of Trustees of the Leland Stanford Junior University Light-sensitive ion-passing molecules
9360472, Jul 22 2005 The Board of Trustees of the Leland Stanford Junior University Cell line, system and method for optical-based screening of ion-channel modulators
9364462, Oct 30 2012 The Regents of the University of California Alpha-1-adrenergic receptor agonist therapy
9364665, Aug 09 2011 Boston Scientific Neuromodulation Corporation Control and/or quantification of target stimulation volume overlap and interface therefor
9364674, Nov 30 2010 The Regents of the University of California Pulse generator for cranial nerve stimulation
9364679, Aug 31 2005 System for providing therapy to a patient
9365628, Dec 16 2011 The Board of Trustees of the Leland Stanford Junior University Opsin polypeptides and methods of use thereof
9367131, Jul 24 2013 Rovi Product Corporation Methods and systems for generating icons associated with providing brain state feedback
9367738, Dec 07 2012 Honda Motor Co., Ltd. Method, apparatus and computer program for calculating current distribution inside brain
9368018, Jul 09 2010 Nokia Technologies Oy Controlling a user alert based on detection of bio-signals and a determination whether the bio-signals pass a significance test
9368265, Jan 13 2014 The Board of Regents of the University of Texas System Apparatuses and methods for cancellation of inhomogeneous magnetic fields induced by non-biological materials within a patient's mouth during magnetic resonance imaging
9370309, Nov 18 2010 The Johns Hopkins University Magnetoencephalography system and method for 3D localization and tracking of electrical activity in brain
9370667, Apr 07 2014 Medical Energetics Ltd Double helix conductor for medical applications using stem cell technology
9375145, Dec 19 2012 The Invention Science Fund II, LLC Systems and methods for controlling acquisition of sensor information
9375151, Aug 25 2010 Angel Medical Systems, Inc. Acute ischemia detection based on parameter value range estimation
9375171, Apr 22 2009 VITAL METRIX INC Probabilistic biomedical parameter estimation apparatus and method of operation therefor
9375564, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
9375571, Jan 15 2013 Electrocore, LLC Mobile phone using non-invasive nerve stimulation
9375573, Aug 05 1998 DiLorenzo Biomedical, LLC Systems and methods for monitoring a patient's neurological disease state
9377348, Jun 15 2012 Canon Kabushiki Kaisha Measuring system
9377515, Nov 26 2009 Korea Research Institute of Standards and Science Flux-locked loop circuit, flux-locked loop method, and squid measuring apparatus
9380976, Mar 11 2013 NEUROSYNC, INC Optical neuroinformatics
9381346, Jul 05 2006 PRECISIS US, INC Treatment of neurological disorders via electrical stimulation, and methods related thereto
9381352, Sep 13 2013 YBRAIN INC. Method for stimulating living body more accurately and apparatus using the same
9383208, Oct 13 2011 Analog Devices, Inc Electromechanical magnetometer and applications thereof
9387320, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
9387338, Oct 02 2006 EMKinetics, Inc. Methods and devices for performing electrical stimulation to treat various conditions
9390233, Jun 18 2008 International Business Machines Corporation Mapping of literature onto regions of interest on neurological images
9392955, Sep 25 2007 Uroval, Inc. Method for measuring a bulbocavernosus reflex
9393406, Sep 21 2011 Sorin CRM SAS Pacing lead in an extended area of a heart cavity, implantable by over the wire technique in the deep coronary network
9393418, Jun 03 2011 Great Lakes Neuro Technologies Inc.; Great Lakes Neurotechnologies Inc Movement disorder therapy system, devices and methods of tuning
9394347, Apr 23 2008 The Board of Trustees of the Leland Stanford Junior University Methods for treating parkinson's disease by optically stimulating target cells
9395425, Aug 24 2012 THE TRUSTEES OF DARTMOUTH COLLEGE Method and apparatus for magnetic susceptibility tomography, magnetoencephalography, and taggant or contrast agent detection
9396533, May 11 2011 SKIDMORE, FRANK M, MR Method, systems and computer program products for medical brain imaging analysis
9396669, Jun 16 2008 Microsoft Technology Licensing, LLC Surgical procedure capture, modelling, and editing interactive playback
9398873, Jun 06 2008 Koninklijke Philips Electronics N V Method of obtaining a desired state in a subject
9399126, Feb 27 2014 THYNC GLOBAL, INC Methods for user control of neurostimulation to modify a cognitive state
9399133, Apr 27 2012 Rhode Island Board of Education, State of Rhode Island and Providence Plantations Non-invasive automated electrical control systems and methods for monitoring animal conditions
9399134, Mar 10 2011 Electrocore, LLC Non-invasive vagal nerve stimulation to treat disorders
9399144, Sep 10 2009 System, method, and applications of using the fundamental code unit and brain language
9401021, Dec 14 2011 ATTI International Services Company, Inc.; ATTI INTERNATIONAL SERVICES COMPANY, INC Method and system for identifying anomalies in medical images especially those including body parts having symmetrical properties
9401033, Mar 04 2014 Method and system for arbitrary-resolution transforms of frequency-space and inverse frequency-space data
9402558, Apr 05 2007 New York University System and method for pain detection and computation of a pain quantification index
9402994, Jul 14 2011 LivaNova USA, Inc Powering of an implantable medical therapy delivery device using far field radiative powering at multiple frequencies
9403000, Nov 11 2011 University of Ireland, Galway; LYONS, DECLAN; QUINN, COLIN Apparatus and methods for prevention of syncope
9403001, Mar 10 2011 ElectroCore LLC Non-invasive magnetic or electrical nerve stimulation to treat gastroparesis, functional dyspepsia, and other functional gastrointestinal disorders
9403009, Sep 30 2011 Nyxoah SA Apparatus and methods for implant coupling indication
9403010, Dec 17 2010 The Regents of the University of California Specific deep brain stimulation for enhancement of memory
9403038, Jul 14 2008 Arizona Board of Regents For and On Behalf Of Arizona State University Methods and devices for modulating cellular activity using ultrasound
9405366, Oct 02 2013 NAQI LOGIX INC Systems and methods for using imagined directions to define an action, function or execution for non-tactile devices
9408530, Apr 12 2006 GEARBOX, LLC Parameter-based navigation by a lumen traveling device
9409013, Oct 20 2009 Nyxoah SA Method for controlling energy delivery as a function of degree of coupling
9409022, Feb 25 2005 Boston Scientific Neuromodulation Corporation Methods and systems for stimulating a motor cortex of the brain to treat a medical condition
9409028, Jun 20 2002 Boston Scientific Neuromodulation Corporation Implantable microstimulators with programmable multielectrode configuration and uses thereof
9410885, Jul 22 2013 Honeywell International Inc Atomic sensor physics package having optically transparent panes and external wedges
9411033, May 11 2005 Regents of the University of Minnesota Methods and apparatus for imaging with magnetic induction
9411935, Aug 18 2010 Boston Scientific Neuromodulation Corporation User interface for segmented neurostimulation leads
9412076, Jul 02 2013 OWL NAVIGATION, INC Methods and systems for a high-resolution brain image pipeline and database program
9412233, May 21 2012 NEUROMASH TECHNOLOGIES LTD Mind controlled casino game
9414029, Sep 28 2010 Canon Kabushiki Kaisha Video control apparatus and video control method
9414749, Nov 21 2012 EMTensor GmbH Electromagnetic tomography solutions for scanning head
9414763, Mar 15 2013 EMTensor GmbH Wearable/man-portable electromagnetic tomographic imaging
9414764, Mar 15 2013 EMTensor GmbH Wearable/man-portable electromagnetic tomographic imaging
9414776, Mar 06 2013 Navigated Technologies, LLC Patient permission-based mobile health-linked information collection and exchange systems and methods
9414780, Apr 18 2013 Digimarc Corporation Dermoscopic data acquisition employing display illumination
9414907, Jun 19 2014 Omega Ophthalmics LLC Prosthetic capsular devices, systems, and methods
9415215, Oct 20 2009 Nyxoah SA Methods for treatment of sleep apnea
9415216, Oct 20 2009 Nyxoah SA Devices for treatment of sleep apnea
9415219, Mar 20 2009 Electrocore, LLC Non-invasive vagal nerve stimulation to treat disorders
9415222, Aug 05 1998 DiLorenzo Biomedical, LLC Monitoring an epilepsy disease state with a supervisory module
9415233, Dec 05 2003 SOFPULSE, INC Apparatus and method for electromagnetic treatment of neurological pain
9418368, Dec 20 2007 The Invention Science Fund I, LLC Methods and systems for determining interest in a cohort-linked avatar
9420970, Oct 22 2013 SONDERMIND INC Method and system for assessment of cognitive function based on mobile device usage
9421258, Nov 05 2010 The Board of Trustees of the Leland Stanford Junior University Optically controlled CNS dysfunction
9421372, Sep 30 2011 MAN & SCIENCE S A Head pain management device having an antenna
9421373, Aug 05 1998 DiLorenzo Biomedical, LLC Apparatus and method for closed-loop intracranial stimulation for optimal control of neurological disease
9421379, Feb 25 2014 Boston Scientific Neuromodulation Corporation Neuromodulation system incorporating multivariate sensing, multivariable pattern recognition, and patient specific adaptation
9424761, Jan 23 2012 VIRTAMED AG Medical simulation system and method with configurable anatomy model manufacturing
9427474, May 22 2008 Ramot at Tel-Aviv University Ltd. Conjugates of a polymer, a bisphosphonate and an anti-angiogenesis agent and uses thereof in the treatment and monitoring of bone related diseases
9427581, Apr 28 2013 Electrocore, LLC Devices and methods for treating medical disorders with evoked potentials and vagus nerve stimulation
9427585, Dec 10 2002 Advanced Neuromodulation Systems, Inc. Systems and methods for enhancing or optimizing neural stimulation therapy for treating symptoms of parkinsons disease and or other movement disorders
9427598, Oct 01 2010 SOFPULSE, INC Method and apparatus for electromagnetic treatment of head, cerebral and neural injury in animals and humans
9430615, Jun 28 2013 Avaya Inc. Personal electronic devices with unobtrusive EKG-based detection of heart rate and rhythm anomalies
9432777, Oct 08 2012 OTICON A S Hearing device with brainwave dependent audio processing
9433797, Dec 05 2003 SOFPULSE, INC Apparatus and method for electromagnetic treatment of neurodegenerative conditions
9434692, Oct 03 2006 ARENA PHARMACEUTICALS, INC Pyrazole derivatives as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
9436989, Jun 03 2011 Bayer HealthCare LLC System and method for rapid quantitative dynamic molecular imaging scans
9438650, Jul 07 2011 FRIENDSHIP LINK PROTOCOL, LLC Relationship networks having link quality metrics with inference and concomitant digital value exchange
9439150, Mar 15 2013 Medtronic, Inc Control of spectral agressors in a physiological signal montoring device
9440063, Dec 30 2008 Research Foundation of the City University of New York Methods for reducing discomfort during electrostimulation, and compositions and apparatus therefor
9440064, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
9440070, Nov 26 2012 THYNC GLOBAL, INC Wearable transdermal electrical stimulation devices and methods of using them
9440084, Jul 11 2008 Medtronic, Inc Programming posture responsive therapy
9440089, Dec 05 2003 SOFPULSE, INC Apparatus and method for electromagnetic treatment of neurological injury or condition caused by a stroke
9440646, Feb 18 2011 Honda Motor Co., Ltd. System and method for responding to driver behavior
9442088, Feb 27 2014 Kimberly-Clark Worldwide, Inc Single coil magnetic induction tomographic imaging
9442525, Feb 21 2014 Samsung Electronics Co., Ltd. Wearable devices
9443141, Jun 02 2008 New York University Method, system, and computer-accessible medium for classification of at least one ICTAL state
9444998, Sep 02 2014 Samsung Electronics Co., Ltd Method for control of camera module based on physiological signal
9445713, Sep 05 2013 JOHNSON & JOHNSON CONSUMER INC Apparatuses and methods for mobile imaging and analysis
9445730, Mar 21 2007 LivaNova USA, Inc Implantable systems and methods for identifying a contra-ictal condition in a subject
9445739, Feb 03 2010 HRL Laboratories, LLC Systems, methods, and apparatus for neuro-robotic goal selection
9445763, Apr 18 2013 Digimarc Corporation Physiologic audio fingerprinting
9446238, Jan 25 2013 Deep brain stimulation of the subcallosal cingulate area for treatment of refractory anorexia nervosa
9448289, Nov 23 2010 Cornell University Background field removal method for MRI using projection onto dipole fields
9449147, Aug 12 2010 HeartFlow, Inc. Method and system for patient-specific modeling of blood flow
9451303, Feb 27 2012 Nielsen Consumer LLC Method and system for gathering and computing an audience's neurologically-based reactions in a distributed framework involving remote storage and computing
9451734, Sep 18 2012 Seiko Epson Corporation Magnetic shielding device and magnetic shielding method
9451883, Mar 04 2009 REGENTS OF THE UNIVERSITY OF CALIFORNIA, A CALIFORNIA CORPORATION Apparatus and method for decoding sensory and cognitive information from brain activity
9451886, Apr 22 2009 VITAL METRIX INC Probabilistic parameter estimation using fused data apparatus and method of use thereof
9451899, Nov 06 2008 VIRTUAL VIDEO REALITY BY RITCHEY, LIMITED LIABILITY CORPORATION Mobile user borne brain activity data and surrounding environment data correlation system
9452287, Jan 21 2013 CALA HEALTH, INC Devices and methods for controlling tremor
9453215, May 29 2008 The Board of Trustees of the Leland Stanford Junior University Cell line, system and method for optical control of secondary messengers
9454646, Apr 19 2010 Nielsen Consumer LLC Short imagery task (SIT) research method
9458208, Nov 14 2008 The Board of Trustees of the Leland Stanford Junior University Optically-based stimulation of target cells and modifications thereto
9459597, Mar 06 2012 DPTechnologies, Inc.; DP TECHNOLOGIES, INC Method and apparatus to provide an improved sleep experience by selecting an optimal next sleep state for a user
9460400, Feb 20 2009 Digital Medical Experts Inc. Expert system for determining patient treatment response
9462733, Sep 11 2013 Seiko Epson Corporation Magnetic shielding apparatus and magnetic shielding method
9462956, Sep 15 2009 Texas Instruments Incorporated Calculating heart rate from acceleration signals containing cardiac activity signals
9462975, Apr 17 2000 adidas AG Systems and methods for ambulatory monitoring of physiological signs
9462977, Jul 05 2011 Saudi Arabian Oil Company Systems, computer medium and computer-implemented methods for monitoring and improving health and productivity of employees
9463327, Jun 17 2014 The Cleveland Clinic Foundation Systems and methods for determining effective stimulation parameters
9468541, May 05 2010 UNIVERSITY OF MARYLAND COLLEGE PARK Time domain-based methods for noninvasive brain-machine interfaces
9468761, Apr 29 2010 LivaNova USA, Inc Validity test adaptive constraint modification for cardiac data used for detection of state changes
9470728, May 09 2012 CARDIOINSIGHT TECHNOLOGIES, INC Channel integrity detection
9471978, Oct 04 2004 BANNER HEALTH Methodologies linking patterns from multi-modality datasets
9472000, Jun 19 2009 VIEWRAY TECHNOLOGIES, INC System and method for performing tomographic image acquisition and reconstruction
9474481, Oct 22 2013 SONDERMIND INC Method and system for assessment of cognitive function based on electronic device usage
9474852, Jun 19 2003 Advanced Neuromodulation Systems, Inc. Method of treating depression, mood disorders and anxiety disorders using neuromodulation
9474903, Mar 15 2013 Boston Scientific Neuromodulation Corporation Clinical response data mapping
9475502, Feb 18 2011 Honda Motor Co., Ltd. Coordinated vehicle response system and method for driver behavior
9480402, Nov 11 2011 Washington University System and method for task-less mapping of brain activity
9480425, Apr 17 2008 Washington University Task-less optical mapping of dynamic brain function using resting state functional connectivity
9480812, Feb 19 2009 Methodology, system, use, and benefits of neuroacoustic frequencies for assessing and improving the health and well-being of living organisms
9480841, Jun 29 2012 Boston Scientific Neuromodulation Corporation Neuromodulation system and method for reducing energy requirements using feedback
9480845, Jun 23 2006 LivaNova USA, Inc Nerve stimulation device with a wearable loop antenna
9480854, Jul 10 2008 Applied Magnetics, LLC Highly precise and low level signal-generating drivers, systems, and methods of use
9483117, Apr 08 2013 Nokia Technologies Oy Apparatus, method and computer program for controlling a near-eye display
9483613, Jul 08 2008 International Business Machines Corporation; Interntional Business Machines Corporation Determination of neuropsychiatric therapy mechanisms of action
9486168, Apr 27 2012 THE BRIGHAM AND WOMEN S HOSPITAL Implantable electrode system
9486381, Dec 16 2011 CHORDATE MEDICAL AB ALS treatment
9486389, Feb 08 2012 GRETAP AG Apparatus and method for calibrating non-invasive desynchronizing neurostimulation
9486618, Aug 27 2013 HALO ABC , LLC; FLOW NEUROSCIENCE, INC Electrode system for electrical stimulation
9486632, Apr 27 2010 Rhode Island Hospital Pain management
9489854, Oct 31 2013 SPRING RIVER HOLDINGS LLC Computing technologies for diagnosis and therapy of language-related disorders
9492084, Jun 18 2004 adidas AG Systems and methods for monitoring subjects in potential physiological distress
9492114, Jun 18 2004 BANNER HEALTH SYSTEMS, INC Accelerated evaluation of treatments to prevent clinical onset of alzheimer's disease
9492120, Jul 05 2011 Saudi Arabian Oil Company Workstation for monitoring and improving health and productivity of employees
9492313, Apr 20 2006 University of Pittsburgh - Of the Commonwealth System of Higher Education Method and apparatus of noninvasive, regional brain thermal stimuli for the treatment of neurological disorders
9492656, Mar 29 2012 LivaNova USA, Inc Implantable nerve wrap for nerve stimulation configured for far field radiative powering
9492678, Jul 14 2011 LivaNova USA, Inc Far field radiative powering of implantable medical therapy delivery devices
9495684, Dec 13 2007 The Invention Science Fund I, LLC Methods and systems for indicating behavior in a population cohort
9497017, Oct 23 2015 Korea Research Institute of Standards and Science Signal processing apparatus and method of controlling clock according to analog to digital conversion thereof
9498134, Mar 28 2016 Cephalogics, LLC Diffuse optical tomography methods and system for determining optical properties
9498628, Nov 21 2014 Medtronic, Inc. Electrode selection for electrical stimulation therapy
9498634, Aug 30 2010 Use of a new stimulation design to treat neurological disorder
9500722, Jan 31 2014 Seiko Epson Corporation Magnetic field measurement apparatus
9501829, Mar 29 2011 Boston Scientific Neuromodulation Corporation System and method for atlas registration
9504390, Mar 04 2011 GLOBALFOUNDRIES Inc. Detecting, assessing and managing a risk of death in epilepsy
9504410, Sep 21 2005 adidas AG Band-like garment for physiological monitoring
9504420, Apr 18 2013 Digimarc Corporation Methods and arrangements for identifying dermatological diagnoses with clinically negligible probabilities
9504788, Apr 24 2008 HARVEST BIO LLC Methods and systems for modifying bioactive agent use
9505402, Feb 18 2011 HONDA MOTOR CO , LTD System and method for responding to driver behavior
9505817, Dec 16 2011 The Board of Trustees of the Leland Stanford Junior University Opsin polypeptides and methods of use thereof
9510790, Feb 27 2015 Samsung Electronics Co., Ltd.; SAMSUNG ELECTRONICS CO , LTD Method for measuring biological signal and wearable electronic device for the same
9513398, Nov 18 2013 Halliburton Energy Services, Inc. Casing mounted EM transducers having a soft magnetic layer
9517020, Aug 04 2011 RAMOT AT TEL AVIV UNIVERSITY LTD IL-1 receptor antagonist-coated electrode and uses thereof
9517031, May 21 2012 NGOGGLE INC EEG hair band
9517222, Feb 08 2007 MED-LIFE DISCOVERIES LP Method for the treatment of senile dementia of the Alzheimer's type
9519981, Nov 04 2011 Siemens Healthcare GmbH Visualizing brain network connectivity
9521958, Mar 05 2012 Seiko Epson Corporation Gas cell and coating method of gas cell
9522085, Jul 02 2008 Board of Regents, The University of Texas System Methods, systems, and devices for treating tinnitus with VNS pairing
9522278, Sep 10 2012 Great Lakes Neurotechnologies Inc Movement disorder therapy system and methods of tuning remotely, intelligently and/or automatically
9522282, Mar 29 2012 LivaNova USA, Inc Powering multiple implantable medical therapy delivery devices using far field radiative powering at multiple frequencies
9522288, Nov 05 2010 The Board of Trustees of the Leland Stanford Junior University Upconversion of light for use in optogenetic methods
9526419, Sep 01 2009 VIVOMETRICS, INC Garment for physiological characteristics monitoring
9526902, May 15 2008 Boston Scientific Neuromodulation Corporation VOA generation system and method using a fiber specific analysis
9526906, Jul 26 2012 Nyxoah SA External resonance matching between an implanted device and an external device
9526913, Apr 21 2009 Duke University; IMMUNOLIGHT, LLC Non-invasive energy upconversion methods and systems
9526914, Apr 21 2009 Duke University; IMMUNOLIGHT, LLC Non-invasive energy upconversion methods and systems
9533113, Jan 04 2007 ORIDION MEDICAL 1987 LTD. Integrated pulmonary index for weaning from mechanical ventilation
9533144, Jun 25 2014 MED-EL Elektromedizinische Geraete GmbH Stimulus signal for simultaneous measurement of auditory steady state responses and psychophysical pitch discrimination
9533147, Oct 24 2011 GLOBALFOUNDRIES Inc.; Flint Hills Scientific, LLC Method, system and apparatus for automated termination of a therapy for an epileptic event upon a determination of effects of a therapy
9533148, Feb 21 2014 Boston Scientific Neuromodulation Corporation Neurostimulation system and method for automatically adjusting stimulation and reducing energy requirements using evoked action potential
9533150, Oct 05 2011 University of Kansas; Case Western Reserve University Methods and associated neural prosthetic devices for bridging brain areas to improve function
9533151, Mar 29 2006 DIGNITY HEALTH Microburst electrical stimulation of cranial nerves for the treatment of medical conditions
9534044, Feb 28 2013 United Arab Emirates University Alpha-synuclein antibodies and uses thereof
9538635, Apr 16 2010 JAMES T BERAN REVOCABLE TYRUST DATED DECEMBER 26, 2002 Varying electrical current and/or conductivity in electrical current channels
9538948, Oct 22 2013 SONDERMIND INC Method and system for assessment of cognitive function based on mobile device usage
9538951, Oct 01 2010 Flint Hills Scientific LLC Detecting, assessing and managing epilepsy using a multi-variate, metric-based classification analysis
9539118, Mar 15 2013 NEUROLUTIONS, INC Brain-controlled body movement assistance devices and methods
9541383, Jul 12 2013 CITIBANK, N A Optical system having a return planar waveguide
9545221, Nov 27 2013 Samsung Electronics Co., Ltd. Electronic system with dynamic localization mechanism and method of operation thereof
9545222, Sep 01 2009 VIVOMETRICS, INC Garment with noninvasive method and system for monitoring physiological characteristics and athletic performance
9545225, Jun 02 2011 CAVUOTO, JAMES Device-independent neurological monitoring system
9545226, Oct 01 2010 Flint Hills Scientific LLC Detecting, quantifying, and/or classifying seizures using multimodal data
9545285, Oct 05 2011 MEDIDATA SOLUTIONS, INC Cardiac catheter employing conformal electronics for mapping
9545510, Feb 12 2008 Intelect Medical, Inc. Directional lead assembly with electrode anchoring prongs
9545515, Aug 02 2012 Health Research, Inc. System and related method to restore and/or improve nervous system functions by modifying specific nervous system pathways
9549691, May 24 2007 Wireless monitoring
9550064, Oct 20 2009 MAN & SCIENCE S A Apparatus and methods for feedback-based nerve modulation
9556149, Apr 02 2008 Arena Pharmaceuticals, Inc. Processes for the preparation of pyrazole derivatives useful as modulators of the 5-HT2A serotonin receptor
9556487, Apr 18 2011 DIAMIR, LLC Methods of using miRNA from bodily fluids for early detection and monitoring of mild cognitive impairment (MCI) and alzheimer's disease (AD)
9557439, Feb 28 2014 Halliburton Energy Services, Inc Optical electric field sensors having passivated electrodes
9558558, Mar 28 2013 KONINKLIJKE PHILIPS N V Interactive follow-up visualization
9560458, Dec 14 2012 OTICON A S Configurable hearing instrument
9560967, Apr 24 2008 HARVEST BIO LLC Systems and apparatus for measuring a bioactive agent effect
9560984, Oct 29 2009 Nielsen Consumer LLC Analysis of controlled and automatic attention for introduction of stimulus material
9560986, Jul 02 2012 CREAVO MEDICAL TECHNOLOGIES LIMITED Magnetometer for medical use
9561380, Aug 28 2012 Boston Scientific Neuromodulation Corporation Point-and-click programming for deep brain stimulation using real-time monopolar review trendlines
9562988, Dec 13 2013 Halliburton Energy Services, Inc Methods and systems of electromagnetic interferometry for downhole environments
9563273, Jun 04 2010 INTERAXON Brainwave actuated apparatus
9563740, Oct 16 2012 THE FLORIDA INTERNATIONAL UNIVERSITY BOARD OF TRUSTEES Neural interface activity simulator
9563950, Mar 20 2013 Cornell University Methods and tools for analyzing brain images
9566426, Aug 31 2011 Electrocore, LLC Systems and methods for vagal nerve stimulation
9567327, Aug 15 2007 ARENA PHARMACEUTICALS, INC Imidazo[1,2-a]pyridine derivatives as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
9568564, Jun 01 2010 INSTITUTE OF PHYSICS, CHINESE ACADEMY OF SCIENCES Magnetic nano-multilayers for magnetic sensors and manufacturing method thereof
9568635, Dec 29 2014 Method and apparatus for mapping the underground soil
9572996, Mar 12 2012 FORSCHUNGSZENTRUM JUELICH GMBH Device and method for stimulation by means of thermal stimuli
9577992, Feb 04 2015 PROPRIOUS TECHNOLOGIES Data encryption/decryption using neuro and neuro-mechanical fingerprints
9578425, Aug 07 2013 Osseofon AB Electric switching device
9579035, Feb 17 2006 General Electric Company Detection of epileptiform activity
9579048, Jul 30 2012 Treefrog Developments, Inc Activity monitoring system with haptic feedback
9579247, Dec 16 2011 CHORDATE MEDICAL AB Treatment of headache disorders
9579457, Mar 15 2013 Method, apparatus and system for automatic treatment of pain
9579506, Jan 25 2008 Flint Hills Scientific, LLC Contingent cardio-protection for epilepsy patients
9582072, Sep 17 2013 Medibotics LLC Motion recognition clothing [TM] with flexible electromagnetic, light, or sonic energy pathways
9582152, Jan 15 2014 Samsung Electronics Co., Ltd. Medical image providing apparatus and medical image processing method of the same
9582925, Dec 24 2013 Commissariat a l Energie Atomique et aux Energies Alternatives Method for processing a volume model, related computer program product and processing system
9584928, Mar 11 2014 OTICON MEDICAL A S; University College London Bilateral hearing assistance system and a method of fitting a bilateral hearing assistance system
9585581, Sep 30 2015 META PLATFORMS TECHNOLOGIES, LLC Real-time biometric detection of oscillatory phenomena and voltage events
9585723, Aug 12 2010 HeartFlow, Inc. Method and system for image processing to determine patient-specific blood flow characteristics
9586047, Jan 28 2005 LivaNova USA, Inc Contingent cardio-protection for epilepsy patients
9586053, Nov 14 2013 Boston Scientific Neuromodulation Corporation Systems, methods, and visualization tools for stimulation and sensing of neural systems with system-level interaction models
9588203, Dec 07 2010 New York University Apparatus, method and computer-accessible medium for determination of electrical properties of tissues and materials using multiple radio frequency measurements
9588490, Oct 21 2014 City University of Hong Kong Neural control holography
9590986, Feb 04 2015 PROPRIUS TECHNOLOGIES S A R L; Aerendir Mobile Inc.; Proprius Technolgies S.A.R.L Local user authentication with neuro and neuro-mechanical fingerprints
9592003, Apr 30 1999 CYBERONICS, INC. Vagal nerve stimulation techniques for treatment of epileptic seizures
9592004, Dec 28 2005 LivaNova USA, Inc Methods and systems for managing epilepsy and other neurological disorders
9592384, Apr 17 2003 Forschungszentrum Jülich GmbH Method for the desynchronization of neural brain activity
9592387, Jul 11 2008 Medtronic, Inc Patient-defined posture states for posture responsive therapy
9592389, May 27 2011 Boston Scientific Neuromodulation Corporation Visualization of relevant stimulation leadwire electrodes relative to selected stimulation information
9592409, Apr 30 2002 THE BRIGHAM AND WOMEN S HOSPITAL Methods for modifying electrical currents in neuronal circuits
9596224, Apr 05 2013 CIRTEC MEDICAL CORP Systems, devices, components and methods for communicating with an IMD using a portable electronic device and a mobile computing device
9597493, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
9597494, Oct 30 2007 NeuroPace, Inc. Systems, methods and devices for a skull/brain interface
9597501, Jan 04 2008 Neurohabilitation Corporation Non-invasive neuromodulation (NINM) for rehabilitation of brain function
9597504, Jan 04 2008 Neurohabilitation Corporation Non-invasive neuromodulation (NINM) for rehabilitation of brain function
9600138, Mar 15 2013 SYNAPTIVE MEDICAL INC Planning, navigation and simulation systems and methods for minimally invasive therapy
9600778, Jul 02 2013 OWL NAVIGATION, INC Method for a brain region location and shape prediction
9604056, Oct 31 2012 The Regents of the University of California; The United States of America—Department of Veterans Affairs Methods and systems for treating neurological movement disorders
9604067, Aug 04 2012 Boston Scientific Neuromodulation Corporation Techniques and methods for storing and transferring registration, atlas, and lead information between medical devices
9604073, Mar 17 2010 The Board of Trustees of the Leland Stanford Junior University Light-sensitive ion-passing molecules
9607023, Jul 20 2012 Ool LLC Insight and algorithmic clustering for automated synthesis
9607377, Jan 24 2013 KINETICOR, INC. Systems, devices, and methods for tracking moving targets
9609453, Jan 14 2015 Method and apparatus for controlling multimedia execution on a device
9610442, May 21 2015 EBT MEDICAL, INC Systems and methods for treatment of urinary dysfunction
9610456, Nov 30 2011 NEURONANO AB Nanowire-based devices for light-induced and electrical stimulation of biological cells
9610459, Jul 24 2009 EMKINETICS, INC Cooling systems and methods for conductive coils
9612295, Apr 04 2011 COLUMBIA PEAK VENTURES, LLC Magnetic shield, program, and selection method
9613184, Apr 18 2008 Medtronic, Inc Analyzing a washout period characteristic for psychiatric disorder therapy delivery
9613186, Mar 31 2014 HeartFlow, Inc. Systems and methods for determining blood flow characteristics using flow ratio
9615746, Jul 05 2011 Saudi Arabian Oil Company Floor mat system and associated, computer medium and computer-implemented methods for monitoring and improving health and productivity of employees
9615749, Aug 22 2011 OXFORD UNIVERSITY INNOVATION LIMITED; OXEHEALTH LIMITED Remote monitoring of vital signs
9615789, Nov 22 2010 The Board of Trustees of the Leland Stanford Junior University Optogenetic magnetic resonance imaging
9616166, Nov 16 2005 Bayer HealthCare LLC Systems and methods of determining injection protocols for diagnostic imaging procedures
9616227, Dec 22 2006 Cornell University Adaptive airway treatment of dorsal displacement disorders in horses
9618591, Nov 24 2009 THE JOHNSON REVOCABLE TRUST DATED 6 25 2003 Magnetic resonance system and method employing a digital squid
9622660, May 25 2012 EMOTIV INC System and method for enabling collaborative analysis of a biosignal
9622672, Jun 07 2013 Indiana University Research and Technology Corporation Digitally invertible universal amplifier for recording and processing of bioelectric signals
9622675, Jan 25 2007 Cyberonics, Inc Communication error alerting in an epilepsy monitoring system
9622676, Dec 17 2007 California Institute of Technology Method of making micromachined neural probes
9622700, Jan 08 2010 Medtronic, Inc. Automated calibration of posture state classification for a medical device
9622702, Apr 03 2014 Nielsen Consumer LLC Methods and apparatus to gather and analyze electroencephalographic data
9622703, Apr 03 2014 Nielsen Consumer LLC Methods and apparatus to gather and analyze electroencephalographic data
9623240, Mar 20 2009 Electrocore, LLC Non-invasive vagal nerve stimulation to treat disorders
9623241, Jun 19 2006 Highland Instruments; HIGHLAND INSTRUMENTS, INC Treatment methods
9626756, Aug 11 1999 Osteoplastics, LLC Methods and systems for producing an implant
9629548, Dec 27 2006 Cardiac Pacemakers Within-patient algorithm to predict heart failure decompensation
9629568, Jan 06 2010 EVOKE NEUROSCIENCE, INC Electrophysiology measurement and training and remote databased and data analysis measurement method and system
9629976, Dec 23 2013 Methods for independent entrainment of visual field zones
9630004, Oct 02 2006 EMKinetics, Inc. Method and apparatus for transdermal stimulation over the palmar and plantar surfaces
9630008, Mar 08 2013 The Regents of the University of California; The Provost, Fellows and Scholars of the College of the Holy and Undivided Trinity of Queen Elizabeth Near Dublin Single channel cochlear implant artifact attenuation in late auditory evoked potentials
9630011, Feb 23 2011 System and methods for diagnosis and treatment of discogenic lower back pain
9630029, Dec 27 2012 Brainsonix Corporation Focused ultrasonic transducer navigation system
9636019, Oct 07 2010 THE MEDICAL RESEARCH, INFRASTRUCTURE, AND HEALTH SERVICES FUND OF THE TEL-AVIV MEDICAL CENTER Device for use in electro-biological signal measurement in the presence of a magnetic field
9636185, Mar 06 2002 MAKO Surgical Corp. System and method for performing surgical procedure using drill guide and robotic device operable in multiple modes
9640167, Aug 20 2014 DREAMWELL, LTD Smart pillows and processes for providing active noise cancellation and biofeedback
9641665, Aug 29 2014 Samsung Electronics Co., Ltd. Method for providing content and electronic device thereof
9642552, Dec 21 2009 Insertion of medical devices through non-orthogonal and orthogonal trajectories within the cranium and methods of using
9642553, Dec 13 2011 Seiko Epson Corporation Magnetic field measuring apparatus and cell array
9642554, Jul 06 2010 Megin Oy Method for adjusting interference signal space in biomagnetic field measurements
9642699, Jun 19 2014 Omega Ophthalmics LLC Prosthetic capsular devices, systems, and methods
9643015, May 27 2011 Boston Scientific Neuromodilation Corporation Collection of clinical data for graphical representation and analysis
9643017, Aug 28 2012 Boston Scientific Neuromodulation Corporation Capture and visualization of clinical effects data in relation to a lead and/or locus of stimulation
9643019, Feb 12 2010 Cyberonics, Inc Neurological monitoring and alerts
9646248, Jul 23 2014 HRL Laboratories, LLC Mapping across domains to extract conceptual knowledge representation from neural systems
9649030, May 01 2012 RightEye, LLC Systems and methods for evaluating human eye tracking
9649036, Apr 22 2009 VITAL METRIX INC Biomedical parameter probabilistic estimation method and apparatus
9649439, Aug 31 2005 Systems and methods for facilitating patient-based adjustment of drug infusion
9649493, Sep 30 2011 MAN & SCIENCE S A System and method for nerve modulation using noncontacting electrodes
9649494, Apr 29 2011 Medtronic, Inc. Electrical stimulation therapy based on head position
9649501, Nov 25 2012 Treatment of thalamocortical dysrhythmia
9651368, Jul 12 2013 CITIBANK, N A Planar waveguide apparatus configured to return light therethrough
9651706, May 14 2015 Halliburton Energy Services, Inc. Fiberoptic tuned-induction sensors for downhole use
9652626, Oct 30 2013 Samsung Electronics Co., Ltd Method for controlling security system and electronic device thereof
9652871, Jan 28 2015 IMPAC MEDICAL SYSTEMS, INC Three dimensional localization of a moving target for adaptive radiation therapy
9655573, Dec 15 2014 WEST VIRGINIA UNIVERSITY ViRPET—combination of virtual reality and PET brain imaging
9655669, May 06 2013 BPCR LIMITED PARTNERSHIP Optimizing treatment using TTFields by changing the frequency during the course of long term tumor treatment
9656069, Jan 04 2008 Non-invasive neuromodulation (NINM) for rehabilitation of brain function
9656075, Mar 23 2009 Flint Hills Scientific, LLC. System and apparatus for automated quantitative assessment, optimization and logging of the effects of a therapy
9656078, Jan 04 2008 Non-invasive neuromodulation (NINM) for rehabilitation of brain function
9656096, Dec 05 2003 SOFPULSE, INC Method and apparatus for electromagnetic enhancement of biochemical signaling pathways for therapeutics and prophylaxis in plants, animals and humans
9659186, Jan 29 2010 Schwegman, Lundberg & Woessner, P.A Controlled use medical application
9659229, Feb 12 2013 OXFORD UNIVERSITY INNOVATION LIMITED; OXEHEALTH LIMITED Method and system for signal analysis
9662049, Sep 30 1998 VTQ IP HOLDING CORPORATION Methods and systems for monitoring patients undergoing treatment for cancer
9662069, Oct 07 2008 MEDIDATA SOLUTIONS, INC Systems, methods, and devices having stretchable integrated circuitry for sensing and delivering therapy
9662083, Apr 10 2014 Toshiba Medical Systems Corporation Medical image display apparatus and medical image display system
9662490, Mar 31 2008 The Feinstein Institutes for Medical Research Methods and systems for reducing inflammation by neuromodulation and administration of an anti-inflammatory drug
9662492, Jul 24 2014 Magstim Group, Incorporated Method for transcranial neurostimulation
9662502, Oct 14 2008 Great Lakes NeuroTechnologies Inc.; GREAT LAKES NEUROTECHNOLOGIES Method and system for tuning of movement disorder therapy devices
9664856, Nov 06 2013 COLUMBIA PEAK VENTURES, LLC Light divider and magnetism measurement apparatus
9665824, Dec 22 2008 The Trustees of Columbia University in the City of New York Rapid image annotation via brain state decoding and visual pattern mining
9665987, Aug 30 2012 WEST TEXAS TECHNOLOGY PARTNERS, LLC Method and apparatus for selectively presenting content
9668694, Mar 14 2013 Nielsen Consumer LLC Methods and apparatus to gather and analyze electroencephalographic data
9669185, Apr 20 2006 University of Pittsburgh—Of the Commonwealth System of Higher Education Methods, devices and systems for treating insomnia by inducing frontal cerebral hypothermia
9669239, Jul 27 2011 UNIVERSITE PIERRE ET MARIE CURIE PARIS 6 Device for treating the sensory capacity of a person and method of treatment with the help of such a device
9672302, Aug 11 1999 Osteoplastics, LLC Producing a three-dimensional model of an implant
9672617, Aug 11 1999 Osteoplastics, LLC Methods and systems for producing an implant
9674621, Aug 19 2013 MED-EL Elektromedizinische Geraete GmbH Auditory prosthesis using stimulation rate as a multiple of periodicity of sensed sound
9675254, Nov 21 2012 EMTensor GmbH Electromagnetic tomography solutions for scanning head
9675255, Nov 21 2012 EMTensor GmbH Electromagnetic tomography solutions for scanning head
9675292, Jun 18 2004 Neuronetrix, Inc. Evoked response testing system for neurological disorders
9675794, Sep 28 2012 NEUROSIGMA, INC. Cutaneous electrode
9675809, Jul 14 2011 LivaNova USA, Inc Circuit, system and method for far-field radiative powering of an implantable medical device
9681814, Jul 10 2013 ALIVECOR, INC. Devices and methods for real-time denoising of electrocardiograms
9681820, Oct 21 2010 HIGHLAND INSTRUMENTS, INC Systems for detecting a condition
9682232, Mar 15 2013 The Regents of the University of Michigan Personalized auditory-somatosensory stimulation to treat tinnitus
9682241, Apr 30 2008 GEARBOX, LLC Intrusion resistant implantable medical device
9684051, Apr 21 2011 Aalto University Foundation System and method for prepolarizing magnetic resonance- or relaxation-based measurements
9684335, Aug 26 2014 Samsung Electronics Co., Ltd. Rotary device and electronic device having the same
9685600, Feb 18 2015 Battelle Savannah River Alliance, LLC Enhanced superconductivity of fullerenes
9687187, Oct 22 2013 SONDERMIND INC Method and system for assessment of cognitive function based on mobile device usage
9687562, Mar 05 2012 Ramot at Tel-Aviv University Ltd. Polymers having therapeutically active agents conjugated thereto, processes of preparing same and uses thereof
9693684, Feb 14 2013 META PLATFORMS TECHNOLOGIES, LLC Systems and methods of eye tracking calibration
9693724, Oct 22 2013 SONDERMIND INC Method and system for assessment of cognitive function based on electronic device usage
9693725, Feb 28 2012 Methods, apparatuses and systems for diagnosis and treatment of mood disorders
9693734, Jul 05 2011 Saudi Arabian Oil Company Systems for monitoring and improving biometric health of employees
9694155, Dec 17 2013 Adjuvant method for the interface of psychosomatic approaches and technology for improving medical outcomes
9694178, Oct 21 2013 NEUROELECTRICS BARCELONA S L ; Beth Isreal Deaconess Medical Center Method and a system for optimizing the configuration of multisite transcranial current stimulation and a computer-readable medium
9694197, Sep 13 2011 BRAINQ TECHNOLOGIES LTD Method and device for enhancing brain activity
9697330, Aug 12 2010 HeartFlow, Inc. Method and system for image processing to determine patient-specific blood flow characteristics
9697336, Jul 28 2009 GEARBOX, LLC Electronically initiating an administration of a neuromodulation treatment regimen chosen in response to contactlessly acquired information
9700256, Apr 29 2010 LivaNova USA, Inc Algorithm for detecting a seizure from cardiac data
9700716, Jun 09 2009 SetPoint Medical Corporation Nerve cuff with pocket for leadless stimulator
9700723, Mar 15 2013 LivaNova USA, Inc Optimization of cranial nerve stimulation to treat seizure disorders during sleep
9704205, Feb 28 2014 Device for implementing body fluid analysis and social networking event planning
9706910, May 29 2014 VIVID VISION INC Interactive system for vision assessment and correction
9706925, Aug 12 2010 HeartFlow, Inc. Method and system for image processing to determine patient-specific blood flow characteristics
9706957, Jan 25 2008 Medtronic, Inc. Sleep stage detection
9706963, Dec 17 2013 Arizona Board of Regents on behalf of Arizona State University Heterogeneous multi-core processing systems and data routing methods for high-throughput model predictive medical systems
9707372, Jul 29 2011 Rosalind Y., Smith System and method for a bioresonance chamber
9707390, Dec 22 2013 The Research Foundation of the City University of New York Apparatus for modulation of effector organs
9707391, Dec 22 2013 The Research Foundation of the City University of New York Method for modulation of effector organs
9707396, Jun 21 2013 Medtronic, Inc Cortical potential monitoring
9710788, Jul 05 2011 Saudi Arabian Oil Company Computer mouse system and associated, computer medium and computer-implemented methods for monitoring and improving health and productivity of employees
9712736, Dec 15 2015 Intel Corporation Electroencephalography (EEG) camera control
9713428, Jan 21 2011 Worcester Polytechnic Institute Physiological parameter monitoring with a mobile communication device
9713433, Nov 13 2013 ELMINDA LTD. Method and system for managing pain
9713444, Sep 23 2008 CLINICAL INK, INC Human-digital media interaction tracking
9713712, Aug 27 2013 HALO ABC , LLC; FLOW NEUROSCIENCE, INC Electrode system for electrical stimulation
9715032, Jul 31 2012 Schlumberger Technology Corporation Nucleur magnetic resonance system with feedback induction coils
9717461, Jan 24 2013 Trex Enterprises Corporation; KINETICOR, INC Systems, devices, and methods for tracking and compensating for patient motion during a medical imaging scan
9717904, Mar 10 2011 Electrocore, LLC Devices and methods for non-invasive capacitive electrical stimulation and their use for vagus nerve stimulation on the neck of a patient
9717920, Sep 10 2012 Great Lakes Neurotechnologies Inc Movement disorder therapy system, devices and methods, and intelligent methods of tuning
9724517, Feb 19 2012 Medtronic, Inc. Brain stimulation response profiling
9729252, Oct 21 2011 CEREVAST MEDICAL, INC Method and system for direct communication
9732039, Oct 03 2006 Arena Pharmeceuticals, Inc. Pyrazole derivatives as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
9734589, Jul 23 2014 KINETICOR, INC Systems, devices, and methods for tracking and compensating for patient motion during a medical imaging scan
9734601, Apr 04 2014 The Board of Trustees of the University of Illinois Highly accelerated imaging and image reconstruction using adaptive sparsifying transforms
9734632, Mar 15 2013 SYNAPTIVE MEDICAL INC Planning, navigation and simulation systems and methods for minimally invasive therapy
9737230, Jan 06 2011 The Johns Hopkins University Seizure detection device and systems
9740710, Sep 02 2014 ELEKTA, INC Systems and methods for segmenting medical images based on anatomical landmark-based features
9740946, Jul 08 2013 Brainlab AG Identification method based on connectivity profiles
9741114, Nov 05 2013 Brainlab AG Quantification of brain vulnerability
9743197, Mar 06 2015 OTICON A S Method, device and system for increasing a person's ability to suppress non-wanted auditory percepts
9743835, Aug 12 2010 HeartFlow, Inc. Method and system for image processing to determine patient-specific blood flow characteristics
9744358, Sep 30 2013 Advanced Bionics AG System and method for neural cochlea stimulation
9763592, May 25 2012 EMOTIV INC System and method for instructing a behavior change in a user
20010003799,
20010009975,
20010014818,
20010020127,
20010021800,
20010029391,
20010049480,
20010051774,
20010051787,
20020000808,
20020005784,
20020006875,
20020013612,
20020013613,
20020016552,
20020017905,
20020017994,
20020024450,
20020032375,
20020033454,
20020035317,
20020035338,
20020037095,
20020042563,
20020052539,
20020055675,
20020058867,
20020059159,
20020072776,
20020072782,
20020077536,
20020082513,
20020082665,
20020085174,
20020087201,
20020091319,
20020091335,
20020091419,
20020095099,
20020097332,
20020099273,
20020099295,
20020099306,
20020099412,
20020099417,
20020099418,
20020103428,
20020103429,
20020103512,
20020107454,
20020112732,
20020117176,
20020128540,
20020128544,
20020128638,
20020138013,
20020151771,
20020151939,
20020158631,
20020173714,
20020177882,
20020182574,
20020183607,
20020183644,
20020188330,
20020193670,
20030001098,
20030004429,
20030009078,
20030009096,
20030013981,
20030018277,
20030018278,
20030023183,
20030023282,
20030028081,
20030028121,
20030028348,
20030031357,
20030032870,
20030032888,
20030032889,
20030035301,
20030036689,
20030040660,
20030045914,
20030046018,
20030055355,
20030068605,
20030070685,
20030074032,
20030081818,
20030083596,
20030083716,
20030088274,
20030093004,
20030093005,
20030093129,
20030097159,
20030097161,
20030100844,
20030105408,
20030114886,
20030120140,
20030120172,
20030125786,
20030128801,
20030130706,
20030130709,
20030135128,
20030139681,
20030144601,
20030149351,
20030149678,
20030153818,
20030158466,
20030158495,
20030158496,
20030158497,
20030158587,
20030160622,
20030163027,
20030163028,
20030167019,
20030171658,
20030171685,
20030171689,
20030176804,
20030181791,
20030181821,
20030181954,
20030181955,
20030185408,
20030187359,
20030195429,
20030195574,
20030199749,
20030204135,
20030216654,
20030225335,
20030225340,
20030229291,
20030233039,
20030233250,
20030234781,
20030236458,
20030236557,
20030236558,
20040002635,
20040006265,
20040006376,
20040010203,
20040015204,
20040015205,
20040019257,
20040019370,
20040024287,
20040030585,
20040034299,
20040039268,
20040049124,
20040049484,
20040059203,
20040059241,
20040064020,
20040064066,
20040068164,
20040068172,
20040068199,
20040072133,
20040073098,
20040073129,
20040073273,
20040077960,
20040077967,
20040078056,
20040079372,
20040082862,
20040082876,
20040088732,
20040092809,
20040096395,
20040097802,
20040101146,
20040116784,
20040116791,
20040116798,
20040116825,
20040117098,
20040122787,
20040122790,
20040127803,
20040131998,
20040133118,
20040133119,
20040133120,
20040133248,
20040133390,
20040138516,
20040138517,
20040138518,
20040138536,
20040138580,
20040138581,
20040138647,
20040138711,
20040138721,
20040140811,
20040143170,
20040144925,
20040145370,
20040151368,
20040152958,
20040152995,
20040153129,
20040158119,
20040158298,
20040158300,
20040166536,
20040167418,
20040172089,
20040172091,
20040172094,
20040181162,
20040184024,
20040186542,
20040193037,
20040193068,
20040193220,
20040195512,
20040199482,
20040204636,
20040204637,
20040204656,
20040204659,
20040210127,
20040210146,
20040210156,
20040215082,
20040220494,
20040220782,
20040225179,
20040230105,
20040243017,
20040243182,
20040254493,
20040260169,
20040260356,
20040263162,
20040267152,
20050004489,
20050007091,
20050010091,
20050010116,
20050015205,
20050018858,
20050019734,
20050020483,
20050020918,
20050021105,
20050025704,
20050027284,
20050032827,
20050033122,
20050033154,
20050033174,
20050033379,
20050038354,
20050043774,
20050049651,
20050059689,
20050059874,
20050060001,
20050060007,
20050060008,
20050060009,
20050060010,
20050065412,
20050065427,
20050075568,
20050079474,
20050079636,
20050080124,
20050080349,
20050080828,
20050085744,
20050096311,
20050096517,
20050106713,
20050107654,
20050113713,
20050118286,
20050119547,
20050119586,
20050124848,
20050124851,
20050124863,
20050131311,
20050135102,
20050136002,
20050137494,
20050137645,
20050144042,
20050148828,
20050148893,
20050148894,
20050148895,
20050149123,
20050149157,
20050153268,
20050154290,
20050154419,
20050154425,
20050154426,
20050156602,
20050159670,
20050159671,
20050165458,
20050167588,
20050171410,
20050182287,
20050182288,
20050182389,
20050182450,
20050182453,
20050182456,
20050182467,
20050182468,
20050182469,
20050187600,
20050192514,
20050192644,
20050192647,
20050197590,
20050197675,
20050197678,
20050209512,
20050209517,
20050209654,
20050209664,
20050209665,
20050209666,
20050215889,
20050216070,
20050216071,
20050222522,
20050222639,
20050228451,
20050228785,
20050240087,
20050240229,
20050240253,
20050244045,
20050245796,
20050251055,
20050251220,
20050256378,
20050256385,
20050256418,
20050267011,
20050267343,
20050267344,
20050267362,
20050267542,
20050273017,
20050277813,
20050277912,
20050283053,
20050283090,
20060004298,
20060004422,
20060009704,
20060009815,
20060014753,
20060015034,
20060015153,
20060018525,
20060020184,
20060036152,
20060036153,
20060041201,
20060047187,
20060047216,
20060047324,
20060047325,
20060051814,
20060052386,
20060052657,
20060052706,
20060058590,
20060058683,
20060058856,
20060061544,
20060064138,
20060064139,
20060064140,
20060069059,
20060069415,
20060074290,
20060074298,
20060074334,
20060074822,
20060078183,
20060079936,
20060082727,
20060084858,
20060084877,
20060087746,
20060089541,
20060089549,
20060094968,
20060094970,
20060094971,
20060094972,
20060095091,
20060095092,
20060100526,
20060100530,
20060100671,
20060102171,
20060106274,
20060106326,
20060106430,
20060106434,
20060111644,
20060116556,
20060122481,
20060129022,
20060129202,
20060129277,
20060129324,
20060135879,
20060135880,
20060136135,
20060142802,
20060149144,
20060149160,
20060149337,
20060152227,
20060153396,
20060155206,
20060155207,
20060155348,
20060155495,
20060161071,
20060161075,
20060161217,
20060161218,
20060161384,
20060167370,
20060167497,
20060167564,
20060167722,
20060170424,
20060173259,
20060173364,
20060173493,
20060173494,
20060173495,
20060173510,
20060176062,
20060178709,
20060184058,
20060184059,
20060188134,
20060189866,
20060189880,
20060189882,
20060189899,
20060191543,
20060195039,
20060195154,
20060195155,
20060200013,
20060200016,
20060200034,
20060200035,
20060200206,
20060204532,
20060206033,
20060206108,
20060206155,
20060206165,
20060206174,
20060212090,
20060212091,
20060217609,
20060217781,
20060217816,
20060224216,
20060224421,
20060225437,
20060229164,
20060233390,
20060235315,
20060235324,
20060235484,
20060235489,
20060239482,
20060241373,
20060241382,
20060241562,
20060241718,
20060247728,
20060251303,
20060252978,
20060252979,
20060258896,
20060258950,
20060259077,
20060265022,
20060276695,
20060281543,
20060281980,
20060282123,
20060287691,
20060293578,
20060293721,
20060293723,
20070000372,
20070005115,
20070005391,
20070007454,
20070008172,
20070014454,
20070015985,
20070016095,
20070016264,
20070019846,
20070021673,
20070021675,
20070021800,
20070025608,
20070027486,
20070027498,
20070027499,
20070027500,
20070027501,
20070031798,
20070032733,
20070032737,
20070032834,
20070036355,
20070036402,
20070038067,
20070038264,
20070038382,
20070043392,
20070043401,
20070049844,
20070049988,
20070050715,
20070055145,
20070060830,
20070060831,
20070060954,
20070060974,
20070060984,
20070066403,
20070066914,
20070066915,
20070066997,
20070067003,
20070067004,
20070072857,
20070078134,
20070081712,
20070083128,
20070093721,
20070093870,
20070100246,
20070100251,
20070100278,
20070100377,
20070100378,
20070100389,
20070100392,
20070100398,
20070100666,
20070112404,
20070118197,
20070127793,
20070129647,
20070129769,
20070129774,
20070135724,
20070135728,
20070138886,
20070142862,
20070142873,
20070142874,
20070149860,
20070150024,
20070150025,
20070150026,
20070150029,
20070156180,
20070156457,
20070159185,
20070161919,
20070162085,
20070162086,
20070165915,
20070167694,
20070167723,
20070167853,
20070167858,
20070167991,
20070173733,
20070173902,
20070179395,
20070179396,
20070179534,
20070179558,
20070179734,
20070184507,
20070191688,
20070191691,
20070191697,
20070191704,
20070191727,
20070197930,
20070198063,
20070203401,
20070203448,
20070208212,
20070208269,
20070209669,
20070213785,
20070213786,
20070225581,
20070225674,
20070225774,
20070225932,
20070233192,
20070233193,
20070238934,
20070239059,
20070244387,
20070244407,
20070249918,
20070249949,
20070249952,
20070250119,
20070250138,
20070255122,
20070255135,
20070255155,
20070255320,
20070255379,
20070255531,
20070259323,
20070260151,
20070265508,
20070265533,
20070273504,
20070273611,
20070276270,
20070276278,
20070276279,
20070276441,
20070276609,
20070280508,
20070282228,
20070287896,
20070291832,
20070293760,
20070299370,
20070299371,
20080001600,
20080001735,
20080004514,
20080004550,
20080004904,
20080009685,
20080009772,
20080013747,
20080015458,
20080015459,
20080021332,
20080021336,
20080021340,
20080021341,
20080021342,
20080021345,
20080027347,
20080027348,
20080027515,
20080033266,
20080033291,
20080033297,
20080033502,
20080033503,
20080033508,
20080033513,
20080036752,
20080039677,
20080039698,
20080039737,
20080039904,
20080042067,
20080045775,
20080045823,
20080045844,
20080046012,
20080046035,
20080049376,
20080051669,
20080051858,
20080058664,
20080058668,
20080058773,
20080064934,
20080065183,
20080069446,
20080071150,
20080071326,
20080074307,
20080077010,
20080077015,
20080077191,
20080081963,
20080082018,
20080086182,
20080091118,
20080091240,
20080097197,
20080097235,
20080097553,
20080097785,
20080103547,
20080103548,
20080109050,
20080119716,
20080119747,
20080119763,
20080119900,
20080123927,
20080125669,
20080125829,
20080125830,
20080125831,
20080128626,
20080132383,
20080139953,
20080140141,
20080140149,
20080140403,
20080147137,
20080154111,
20080154126,
20080154148,
20080154331,
20080154332,
20080157980,
20080161700,
20080161879,
20080161880,
20080161881,
20080161886,
20080161894,
20080162182,
20080167535,
20080167540,
20080167569,
20080167571,
20080177195,
20080177196,
20080177197,
20080183072,
20080183097,
20080188765,
20080194981,
20080195166,
20080200831,
20080208072,
20080208073,
20080208280,
20080208285,
20080214902,
20080215112,
20080219917,
20080221400,
20080221401,
20080221441,
20080221472,
20080221969,
20080228077,
20080228100,
20080228239,
20080229408,
20080230702,
20080230705,
20080234113,
20080234601,
20080235469,
20080241804,
20080242521,
20080242976,
20080243005,
20080243014,
20080243017,
20080243021,
20080247618,
20080249430,
20080249589,
20080255469,
20080255816,
20080255949,
20080257349,
20080260212,
20080262327,
20080262367,
20080262371,
20080269542,
20080269812,
20080269833,
20080269834,
20080269840,
20080269843,
20080275327,
20080275340,
20080275526,
20080279436,
20080281238,
20080281381,
20080281667,
20080286453,
20080287774,
20080287821,
20080288018,
20080294019,
20080294063,
20080298653,
20080298659,
20080304691,
20080304731,
20080306365,
20080310697,
20080311549,
20080317317,
20080319326,
20080319505,
20090005654,
20090005667,
20090005675,
20090006001,
20090009284,
20090012387,
20090018407,
20090018419,
20090018429,
20090018431,
20090018432,
20090018462,
20090022825,
20090024007,
20090024050,
20090030476,
20090030930,
20090033333,
20090036781,
20090036791,
20090036950,
20090039889,
20090043221,
20090048507,
20090048530,
20090054788,
20090054800,
20090054801,
20090054946,
20090054958,
20090058660,
20090062660,
20090062670,
20090062676,
20090062679,
20090062680,
20090062696,
20090062698,
20090069707,
20090074279,
20090076339,
20090076399,
20090076400,
20090076406,
20090076407,
20090076567,
20090078875,
20090082688,
20090082689,
20090082690,
20090082829,
20090083071,
20090088658,
20090088680,
20090093403,
20090093862,
20090094305,
20090099474,
20090099627,
20090099783,
20090105785,
20090112117,
20090112273,
20090112277,
20090112278,
20090112279,
20090112280,
20090112281,
20090112523,
20090118593,
20090118610,
20090118622,
20090118636,
20090118780,
20090118786,
20090118787,
20090119154,
20090124869,
20090124921,
20090124922,
20090124923,
20090131995,
20090132275,
20090137915,
20090137923,
20090143654,
20090148019,
20090149148,
20090149736,
20090156907,
20090156954,
20090156955,
20090156956,
20090157323,
20090157481,
20090157482,
20090157625,
20090157660,
20090157662,
20090157751,
20090157813,
20090163777,
20090163980,
20090163981,
20090163982,
20090164131,
20090164132,
20090164302,
20090164401,
20090164403,
20090164458,
20090164503,
20090164549,
20090171164,
20090171232,
20090171240,
20090171405,
20090172540,
20090177050,
20090177090,
20090177108,
20090177144,
20090179642,
20090182211,
20090187230,
20090191131,
20090192394,
20090192556,
20090198144,
20090198145,
20090204015,
20090209831,
20090209835,
20090209845,
20090210018,
20090216091,
20090216146,
20090216288,
20090220425,
20090220429,
20090221904,
20090221928,
20090221930,
20090227876,
20090227877,
20090227882,
20090227889,
20090234419,
20090240119,
20090243756,
20090246138,
20090247893,
20090247894,
20090259277,
20090261832,
20090264785,
20090264789,
20090264952,
20090264954,
20090264955,
20090264956,
20090264957,
20090264958,
20090264967,
20090267758,
20090270687,
20090270688,
20090270692,
20090270693,
20090270694,
20090270754,
20090270758,
20090270786,
20090270944,
20090271011,
20090271120,
20090271122,
20090271347,
20090275853,
20090276011,
20090276012,
20090280153,
20090281400,
20090281448,
20090281594,
20090287035,
20090287107,
20090287108,
20090287271,
20090287272,
20090287273,
20090287274,
20090287467,
20090290767,
20090290772,
20090292180,
20090292478,
20090292551,
20090292713,
20090292724,
20090297000,
20090299126,
20090299169,
20090299435,
20090304582,
20090306491,
20090306531,
20090306532,
20090306534,
20090306741,
20090311655,
20090312595,
20090312624,
20090312646,
20090312663,
20090312664,
20090312668,
20090312808,
20090312817,
20090312998,
20090316925,
20090316968,
20090316969,
20090318773,
20090318779,
20090318794,
20090319000,
20090319001,
20090319002,
20090319004,
20090322331,
20090323049,
20090326353,
20090326604,
20090326605,
20090327068,
20100003656,
20100004500,
20100004705,
20100004717,
20100004762,
20100004977,
20100010289,
20100010316,
20100010363,
20100010364,
20100010365,
20100010366,
20100010383,
20100010388,
20100010391,
20100010392,
20100010571,
20100010572,
20100010573,
20100010574,
20100010575,
20100010576,
20100010577,
20100010578,
20100010579,
20100010580,
20100010584,
20100010585,
20100010587,
20100010588,
20100010589,
20100010590,
20100010844,
20100014730,
20100014732,
20100015583,
20100016783,
20100017001,
20100021378,
20100022820,
20100023089,
20100028841,
20100030073,
20100030089,
20100030097,
20100030287,
20100036211,
20100036233,
20100036276,
20100036453,
20100041949,
20100041958,
20100041962,
20100041964,
20100042011,
20100042578,
20100043795,
20100045467,
20100049069,
20100049075,
20100049276,
20100049482,
20100056276,
20100056854,
20100056939,
20100057159,
20100057160,
20100057655,
20100063368,
20100063563,
20100068751,
20100069724,
20100069739,
20100069762,
20100069775,
20100069777,
20100069780,
20100070001,
20100076249,
20100076253,
20100076274,
20100076333,
20100076334,
20100076338,
20100076525,
20100079292,
20100080432,
20100081860,
20100081861,
20100082506,
20100087719,
20100087900,
20100090835,
20100092934,
20100094103,
20100094152,
20100094154,
20100094155,
20100098289,
20100099954,
20100099975,
20100100036,
20100100164,
20100106041,
20100106043,
20100106044,
20100106217,
20100113959,
20100114190,
20100114192,
20100114193,
20100114237,
20100114272,
20100114813,
20100121415,
20100125219,
20100125304,
20100125561,
20100130811,
20100130812,
20100130869,
20100130878,
20100131030,
20100131034,
20100132448,
20100134113,
20100135556,
20100137728,
20100137937,
20100142774,
20100143256,
20100145215,
20100145219,
20100145427,
20100145428,
20100152621,
20100160737,
20100163027,
20100163028,
20100163035,
20100165593,
20100168053,
20100168525,
20100168529,
20100168602,
20100172567,
20100174161,
20100174533,
20100179415,
20100179447,
20100185113,
20100189318,
20100191095,
20100191124,
20100191139,
20100191304,
20100191305,
20100195770,
20100197610,
20100197993,
20100198090,
20100198098,
20100198101,
20100198282,
20100198296,
20100198519,
20100204604,
20100204614,
20100204748,
20100204749,
20100204750,
20100217100,
20100217146,
20100217341,
20100217348,
20100219820,
20100222640,
20100222694,
20100222845,
20100224188,
20100231221,
20100231327,
20100234705,
20100234752,
20100234753,
20100238763,
20100241020,
20100241195,
20100241449,
20100245093,
20100248275,
20100249573,
20100249627,
20100249635,
20100249638,
20100256592,
20100258126,
20100260402,
20100261977,
20100261993,
20100262377,
20100268055,
20100268057,
20100268108,
20100268288,
20100274106,
20100274141,
20100274147,
20100274303,
20100274305,
20100274308,
20100274577,
20100274578,
20100280332,
20100280334,
20100280335,
20100280372,
20100280403,
20100280500,
20100280571,
20100280574,
20100280579,
20100286549,
20100286747,
20100292602,
20100292752,
20100293002,
20100293115,
20100298624,
20100298735,
20100303101,
20100305962,
20100305963,
20100312188,
20100312579,
20100318025,
20100318160,
20100322488,
20100322497,
20100324441,
20100331649,
20100331715,
20100331976,
20110004115,
20110004270,
20110004283,
20110004412,
20110007129,
20110009715,
20110009729,
20110009752,
20110009777,
20110009920,
20110009928,
20110015209,
20110015469,
20110015501,
20110015515,
20110015536,
20110015539,
20110021899,
20110021970,
20110022981,
20110028798,
20110028799,
20110028802,
20110028825,
20110028827,
20110028859,
20110029038,
20110029044,
20110034812,
20110034821,
20110034822,
20110034912,
20110035231,
20110038515,
20110038850,
20110040202,
20110040356,
20110040546,
20110040547,
20110040713,
20110043759,
20110046451,
20110046473,
20110046491,
20110050232,
20110054272,
20110054279,
20110054345,
20110054562,
20110054569,
20110060382,
20110066005,
20110066041,
20110066042,
20110066053,
20110074396,
20110077503,
20110077538,
20110077548,
20110077721,
20110082154,
20110082360,
20110082381,
20110082522,
20110087125,
20110087127,
20110092800,
20110092834,
20110092839,
20110092882,
20110093033,
20110098583,
20110098778,
20110105859,
20110105915,
20110105938,
20110105998,
20110106206,
20110106750,
20110110868,
20110112379,
20110112381,
20110112394,
20110112426,
20110112427,
20110112590,
20110115624,
20110118536,
20110118618,
20110118619,
20110119212,
20110125046,
20110125048,
20110125077,
20110125078,
20110125203,
20110125238,
20110129129,
20110130615,
20110130643,
20110130675,
20110137371,
20110137381,
20110144520,
20110144521,
20110150253,
20110152284,
20110152710,
20110152729,
20110152967,
20110152988,
20110160543,
20110160607,
20110160608,
20110160795,
20110160796,
20110161011,
20110162645,
20110166430,
20110166471,
20110166546,
20110172500,
20110172509,
20110172553,
20110172554,
20110172562,
20110172564,
20110172567,
20110172725,
20110172732,
20110172738,
20110172739,
20110172743,
20110172927,
20110178359,
20110178441,
20110178442,
20110178581,
20110181422,
20110182501,
20110184305,
20110184487,
20110184650,
20110190569,
20110190600,
20110190846,
20110191275,
20110191350,
20110196693,
20110201944,
20110207988,
20110208012,
20110208094,
20110208264,
20110208539,
20110213200,
20110213222,
20110217240,
20110218405,
20110218453,
20110218456,
20110218950,
20110224569,
20110224570,
20110224571,
20110224602,
20110224749,
20110229005,
20110230701,
20110230738,
20110230755,
20110230938,
20110238130,
20110238136,
20110245709,
20110245734,
20110251583,
20110251985,
20110256520,
20110257501,
20110257517,
20110257519,
20110263962,
20110263968,
20110263995,
20110264182,
20110270074,
20110270095,
20110270096,
20110270117,
20110270346,
20110270347,
20110270348,
20110270579,
20110270914,
20110275927,
20110276107,
20110276112,
20110282225,
20110282230,
20110282234,
20110288119,
20110288400,
20110288424,
20110288431,
20110293193,
20110295142,
20110295143,
20110295166,
20110295338,
20110295344,
20110295345,
20110295346,
20110295347,
20110298706,
20110301436,
20110301439,
20110301441,
20110301448,
20110301486,
20110301487,
20110301488,
20110301529,
20110306845,
20110306846,
20110307029,
20110307030,
20110307079,
20110308789,
20110311021,
20110311489,
20110313268,
20110313274,
20110313308,
20110313487,
20110313760,
20110319482,
20110319724,
20110319726,
20110319975,
20120003615,
20120004518,
20120004561,
20120004564,
20120004579,
20120004749,
20120010493,
20120010536,
20120011927,
20120016218,
20120016252,
20120016336,
20120016430,
20120016432,
20120016435,
20120021394,
20120022336,
20120022340,
20120022343,
20120022350,
20120022351,
20120022365,
20120022384,
20120022392,
20120022611,
20120022844,
20120022884,
20120029320,
20120029378,
20120029379,
20120029591,
20120029601,
20120035428,
20120035431,
20120035433,
20120035698,
20120035765,
20120036004,
20120041279,
20120041318,
20120041319,
20120041320,
20120041321,
20120041322,
20120041323,
20120041324,
20120041330,
20120041498,
20120041735,
20120041739,
20120046531,
20120046535,
20120046711,
20120046715,
20120046971,
20120052469,
20120052905,
20120053394,
20120053433,
20120053449,
20120053473,
20120053476,
20120053478,
20120053479,
20120053483,
20120053491,
20120053508,
20120053919,
20120053921,
20120059246,
20120059273,
20120059431,
20120060851,
20120065536,
20120070044,
20120071771,
20120078115,
20120078323,
20120078327,
20120080305,
20120083668,
20120083690,
20120083700,
20120083701,
20120083708,
20120088987,
20120088992,
20120089004,
20120089205,
20120092156,
20120092157,
20120095352,
20120095357,
20120100514,
20120101326,
20120101387,
20120101401,
20120101402,
20120101430,
20120101544,
20120108909,
20120108918,
20120108995,
20120108997,
20120108998,
20120108999,
20120109020,
20120116149,
20120116179,
20120116235,
20120116244,
20120116475,
20120116741,
20120123232,
20120123290,
20120125337,
20120128683,
20120130204,
20120130228,
20120130229,
20120130300,
20120130641,
20120136242,
20120136274,
20120136605,
20120143038,
20120143074,
20120143075,
20120143104,
20120143285,
20120145152,
20120149042,
20120149997,
20120150255,
20120150257,
20120150262,
20120150516,
20120150545,
20120157804,
20120157963,
20120158092,
20120159656,
20120162002,
20120163689,
20120164613,
20120165624,
20120165631,
20120165696,
20120165898,
20120165899,
20120165904,
20120172682,
20120172689,
20120172743,
20120177716,
20120179071,
20120179228,
20120184801,
20120184826,
20120185020,
20120191000,
20120191158,
20120191542,
20120195860,
20120197092,
20120197153,
20120197163,
20120197322,
20120203079,
20120203087,
20120203130,
20120203131,
20120203133,
20120203725,
20120207362,
20120209126,
20120209136,
20120209139,
20120209346,
20120212353,
20120215114,
20120215448,
20120219195,
20120219507,
20120220843,
20120220889,
20120221310,
20120226091,
20120226130,
20120226185,
20120226334,
20120232327,
20120232376,
20120232433,
20120238890,
20120242501,
20120245464,
20120245474,
20120245481,
20120245493,
20120245655,
20120249274,
20120253101,
20120253141,
20120253168,
20120253219,
20120253249,
20120253261,
20120253421,
20120253429,
20120253434,
20120253442,
20120259249,
20120262250,
20120262558,
20120263393,
20120265080,
20120265262,
20120265267,
20120265270,
20120265271,
20120268272,
20120269385,
20120271148,
20120271151,
20120271183,
20120271189,
20120271190,
20120271374,
20120271375,
20120271376,
20120271377,
20120271380,
20120277545,
20120277548,
20120277816,
20120277833,
20120283502,
20120283604,
20120288143,
20120289854,
20120289869,
20120290058,
20120296182,
20120296241,
20120296253,
20120296569,
20120302842,
20120302845,
20120302856,
20120302867,
20120302894,
20120302912,
20120303080,
20120303087,
20120310050,
20120310100,
20120310105,
20120310106,
20120310107,
20120310298,
20120316622,
20120316630,
20120316793,
20120321152,
20120321160,
20120321759,
20120323108,
20120323132,
20120330109,
20120330369,
20130006124,
20130006332,
20130009783,
20130011819,
20130012786,
20130012787,
20130012788,
20130012789,
20130012790,
20130012802,
20130012804,
20130012830,
20130013327,
20130013339,
20130013667,
20130018435,
20130018438,
20130018439,
20130018440,
20130018592,
20130018596,
20130019325,
20130023783,
20130028496,
20130030241,
20130030257,
20130031038,
20130034837,
20130035579,
20130039498,
20130041235,
20130041281,
20130046151,
20130046193,
20130046358,
20130046715,
20130053656,
20130054214,
20130054215,
20130058548,
20130060110,
20130060125,
20130060158,
20130063434,
20130063550,
20130064438,
20130066350,
20130066391,
20130066392,
20130066394,
20130066395,
20130066618,
20130069780,
20130070929,
20130072292,
20130072775,
20130072780,
20130072807,
20130072996,
20130073022,
20130076885,
20130079606,
20130079621,
20130079647,
20130079656,
20130079657,
20130080127,
20130080489,
20130085678,
20130089503,
20130090454,
20130090706,
20130091941,
20130095459,
20130096391,
20130096393,
20130096394,
20130096408,
20130096441,
20130096453,
20130096454,
20130096839,
20130096840,
20130102833,
20130102877,
20130102897,
20130102907,
20130102919,
20130104066,
20130109995,
20130109996,
20130110616,
20130113816,
20130116520,
20130116540,
20130116561,
20130116578,
20130116588,
20130116748,
20130118494,
20130120246,
20130121984,
20130123568,
20130123584,
20130123607,
20130123684,
20130127708,
20130127980,
20130130799,
20130131438,
20130131461,
20130131537,
20130131746,
20130131753,
20130131755,
20130132029,
20130137717,
20130137936,
20130137938,
20130138002,
20130138176,
20130138177,
20130141103,
20130144106,
20130144107,
20130144108,
20130144183,
20130144192,
20130144353,
20130144537,
20130150650,
20130150651,
20130150659,
20130150702,
20130150921,
20130151163,
20130158883,
20130159041,
20130165766,
20130165804,
20130165812,
20130165846,
20130165996,
20130167360,
20130172663,
20130172686,
20130172691,
20130172716,
20130172763,
20130172767,
20130172772,
20130172774,
20130178693,
20130178718,
20130178733,
20130178913,
20130182860,
20130184218,
20130184516,
20130184552,
20130184558,
20130184597,
20130184603,
20130184639,
20130184728,
20130184781,
20130184786,
20130184792,
20130184997,
20130185144,
20130185145,
20130188830,
20130188854,
20130189663,
20130190577,
20130190642,
20130197321,
20130197322,
20130197328,
20130197339,
20130197401,
20130197944,
20130203019,
20130204085,
20130204122,
20130204144,
20130204150,
20130211183,
20130211224,
20130211238,
20130211276,
20130211291,
20130211728,
20130217982,
20130218043,
20130218053,
20130218232,
20130218233,
20130218819,
20130221961,
20130223709,
20130225940,
20130225953,
20130225992,
20130226261,
20130226408,
20130226464,
20130231574,
20130231580,
20130231709,
20130231716,
20130231721,
20130231947,
20130234823,
20130235550,
20130237541,
20130237874,
20130238049,
20130238050,
20130238053,
20130238063,
20130242262,
20130243287,
20130244323,
20130245416,
20130245422,
20130245424,
20130245464,
20130245466,
20130245485,
20130245486,
20130245711,
20130245712,
20130245886,
20130251641,
20130253363,
20130253612,
20130255586,
20130261490,
20130261506,
20130261703,
20130266163,
20130267760,
20130267866,
20130267928,
20130274562,
20130274580,
20130274586,
20130274625,
20130275159,
20130281758,
20130281759,
20130281798,
20130281811,
20130281879,
20130281890,
20130282075,
20130282339,
20130289360,
20130289364,
20130289385,
20130289386,
20130289401,
20130289413,
20130289417,
20130289424,
20130289433,
20130289653,
20130289669,
20130293844,
20130295016,
20130296406,
20130296637,
20130300573,
20130303828,
20130303934,
20130304153,
20130304159,
20130304472,
20130308099,
20130309278,
20130310422,
20130310660,
20130310909,
20130314243,
20130317380,
20130317382,
20130317384,
20130317474,
20130317568,
20130317580,
20130318546,
20130324880,
20130330428,
20130338449,
20130338450,
20130338459,
20130338518,
20130338526,
20130338738,
20130338803,
20130339043,
20130344465,
20130345522,
20130345523,
20140000630,
20140003696,
20140005518,
20140005743,
20140005744,
20140005988,
20140012061,
20140012110,
20140012133,
20140012153,
20140015852,
20140018649,
20140018792,
20140019165,
20140023999,
20140025133,
20140025396,
20140025397,
20140029830,
20140031703,
20140031889,
20140031903,
20140032512,
20140038147,
20140039279,
20140039290,
20140039336,
20140039571,
20140039577,
20140039578,
20140039975,
20140046203,
20140046208,
20140046407,
20140051044,
20140051960,
20140051961,
20140052213,
20140055284,
20140056815,
20140057232,
20140058189,
20140058218,
20140058219,
20140058241,
20140058289,
20140058292,
20140058528,
20140062472,
20140063054,
20140063055,
20140066739,
20140066763,
20140066796,
20140067740,
20140070958,
20140072127,
20140072130,
20140073863,
20140073864,
20140073866,
20140073870,
20140073875,
20140073876,
20140073877,
20140073878,
20140073898,
20140073948,
20140073949,
20140073951,
20140073953,
20140073954,
20140073955,
20140073956,
20140073960,
20140073961,
20140073963,
20140073965,
20140073966,
20140073967,
20140073968,
20140073974,
20140073975,
20140074060,
20140074179,
20140074180,
20140074188,
20140077612,
20140077946,
20140081071,
20140081114,
20140081115,
20140081347,
20140081353,
20140088341,
20140088377,
20140094710,
20140094719,
20140094720,
20140098981,
20140100467,
20140100633,
20140101084,
20140104059,
20140105436,
20140107397,
20140107398,
20140107401,
20140107464,
20140107519,
20140107521,
20140107525,
20140107728,
20140107935,
20140111335,
20140113367,
20140114165,
20140114205,
20140114207,
20140114242,
20140114889,
20140119621,
20140121446,
20140121476,
20140121554,
20140121565,
20140122379,
20140128762,
20140128763,
20140128764,
20140128938,
20140133720,
20140133722,
20140135642,
20140135680,
20140135873,
20140135879,
20140135886,
20140136585,
20140140567,
20140142448,
20140142653,
20140142654,
20140142669,
20140143064,
20140148479,
20140148657,
20140148693,
20140148716,
20140148723,
20140148726,
20140148872,
20140151563,
20140152673,
20140154647,
20140154650,
20140155430,
20140155706,
20140155714,
20140155730,
20140155740,
20140155770,
20140155772,
20140155952,
20140156000,
20140159862,
20140161352,
20140163328,
20140163330,
20140163331,
20140163332,
20140163333,
20140163335,
20140163336,
20140163337,
20140163368,
20140163385,
20140163409,
20140163425,
20140163627,
20140163643,
20140163893,
20140163897,
20140171749,
20140171757,
20140171819,
20140171820,
20140174277,
20140175261,
20140176944,
20140179980,
20140180088,
20140180092,
20140180093,
20140180094,
20140180095,
20140180096,
20140180097,
20140180099,
20140180100,
20140180112,
20140180113,
20140180145,
20140180153,
20140180160,
20140180161,
20140180176,
20140180177,
20140180194,
20140180358,
20140180597,
20140184550,
20140187901,
20140187994,
20140188006,
20140188770,
20140193336,
20140194702,
20140194720,
20140194726,
20140194758,
20140194759,
20140194768,
20140194769,
20140194780,
20140194793,
20140200414,
20140200432,
20140200623,
20140203797,
20140206981,
20140207224,
20140207432,
20140211593,
20140213842,
20140213843,
20140213844,
20140213937,
20140213961,
20140214135,
20140214330,
20140214335,
20140221726,
20140221866,
20140222113,
20140222406,
20140226131,
20140226888,
20140228620,
20140228649,
20140228651,
20140228653,
20140228702,
20140232516,
20140235826,
20140235965,
20140236039,
20140236077,
20140236272,
20140236492,
20140237073,
20140243608,
20140243613,
20140243614,
20140243621,
20140243628,
20140243647,
20140243652,
20140243663,
20140243694,
20140243714,
20140243926,
20140243934,
20140245191,
20140247970,
20140249360,
20140249396,
20140249429,
20140249445,
20140249447,
20140249454,
20140249608,
20140249791,
20140249792,
20140257047,
20140257073,
20140257118,
20140257128,
20140257132,
20140257147,
20140257430,
20140257437,
20140257438,
20140266696,
20140266787,
20140270438,
20140271483,
20140275716,
20140275741,
20140275807,
20140275847,
20140275851,
20140275886,
20140275889,
20140275891,
20140275944,
20140276012,
20140276013,
20140276014,
20140276090,
20140276123,
20140276130,
20140276181,
20140276183,
20140276185,
20140276187,
20140276194,
20140276549,
20140276702,
20140276944,
20140277255,
20140277256,
20140277282,
20140277286,
20140277582,
20140279341,
20140279746,
20140288381,
20140288614,
20140288620,
20140288953,
20140289172,
20140296646,
20140296655,
20140296724,
20140296733,
20140296750,
20140297397,
20140300532,
20140303424,
20140303425,
20140303452,
20140303453,
20140303454,
20140303486,
20140303508,
20140303511,
20140304773,
20140309484,
20140309614,
20140309881,
20140309943,
20140313303,
20140315169,
20140316191,
20140316192,
20140316217,
20140316221,
20140316230,
20140316235,
20140316243,
20140316248,
20140316278,
20140323849,
20140323899,
20140323900,
20140323924,
20140323946,
20140324118,
20140324138,
20140328487,
20140330093,
20140330102,
20140330157,
20140330159,
20140330268,
20140330334,
20140330335,
20140330336,
20140330337,
20140330345,
20140330357,
20140330394,
20140330404,
20140330580,
20140335489,
20140336473,
20140336489,
20140336514,
20140336547,
20140336730,
20140340084,
20140343397,
20140343399,
20140343408,
20140343463,
20140343882,
20140347265,
20140347491,
20140348183,
20140348412,
20140350353,
20140350369,
20140350380,
20140350431,
20140350436,
20140350634,
20140350636,
20140350864,
20140354278,
20140355859,
20140357507,
20140357932,
20140357935,
20140357936,
20140357962,
20140358024,
20140358025,
20140358067,
20140358193,
20140358199,
20140364721,
20140364746,
20140369537,
20140370479,
20140371515,
20140371516,
20140371544,
20140371573,
20140371599,
20140371611,
20140371984,
20140378809,
20140378810,
20140378815,
20140378830,
20140378851,
20140378941,
20140379620,
20150002815,
20150003698,
20150003699,
20150005592,
20150005594,
20150005640,
20150005644,
20150005646,
20150005660,
20150005680,
20150005839,
20150005840,
20150005841,
20150006186,
20150008916,
20150010223,
20150011866,
20150011877,
20150011907,
20150012054,
20150012057,
20150012111,
20150012466,
20150016618,
20150017115,
20150018665,
20150018699,
20150018702,
20150018705,
20150018706,
20150018758,
20150018893,
20150018905,
20150019241,
20150019266,
20150024356,
20150025351,
20150025408,
20150025410,
20150025421,
20150025422,
20150025610,
20150025917,
20150026446,
20150029087,
20150030220,
20150032017,
20150032044,
20150032178,
20150033245,
20150033258,
20150033259,
20150033262,
20150033266,
20150033363,
20150035959,
20150038804,
20150038812,
20150038822,
20150038869,
20150039066,
20150039110,
20150042477,
20150044138,
20150045606,
20150045607,
20150045686,
20150051655,
20150051656,
20150051657,
20150051658,
20150051659,
20150051663,
20150051668,
20150057512,
20150057715,
20150065803,
20150065831,
20150065838,
20150065839,
20150065845,
20150066124,
20150068069,
20150069846,
20150071907,
20150072394,
20150073141,
20150073237,
20150073249,
20150073294,
20150073306,
20150073505,
20150073722,
20150080327,
20150080671,
20150080674,
20150080695,
20150080703,
20150080746,
20150080753,
20150080985,
20150081226,
20150081299,
20150087931,
20150088015,
20150088024,
20150088093,
20150088120,
20150088224,
20150088228,
20150088478,
20150091730,
20150091791,
20150092949,
20150093729,
20150094962,
20150096564,
20150099941,
20150099946,
20150099959,
20150099962,
20150103360,
20150105631,
20150105641,
20150105701,
20150105837,
20150105844,
20150112222,
20150112403,
20150112409,
20150112899,
20150119652,
20150119658,
20150119689,
20150119698,
20150119743,
20150119745,
20150119746,
20150119794,
20150119898,
20150119956,
20150120007,
20150123653,
20150124220,
20150126821,
20150126845,
20150126848,
20150126873,
20150133716,
20150133811,
20150133812,
20150133830,
20150134031,
20150134264,
20150137817,
20150137988,
20150140528,
20150141529,
20150141773,
20150141789,
20150141794,
20150142082,
20150145519,
20150145676,
20150148617,
20150148619,
20150148700,
20150148878,
20150150122,
20150150473,
20150150475,
20150150530,
20150150753,
20150151142,
20150153477,
20150154721,
20150154764,
20150154889,
20150157235,
20150157266,
20150157271,
20150157859,
20150161326,
20150161348,
20150161738,
20150164349,
20150164362,
20150164375,
20150164404,
20150164431,
20150165226,
20150165239,
20150167459,
20150174362,
20150174398,
20150174403,
20150174405,
20150174406,
20150174407,
20150174418,
20150177413,
20150178631,
20150178978,
20150181840,
20150182417,
20150182753,
20150182756,
20150186923,
20150190062,
20150190070,
20150190077,
20150190085,
20150190094,
20150190636,
20150190637,
20150192532,
20150192776,
20150196213,
20150196246,
20150196249,
20150196800,
20150199010,
20150199121,
20150200046,
20150201849,
20150201879,
20150202330,
20150202428,
20150202447,
20150203822,
20150206051,
20150206174,
20150208940,
20150208975,
20150208978,
20150208982,
20150208994,
20150212168,
20150213012,
20150213019,
20150213020,
20150213191,
20150215412,
20150216436,
20150216439,
20150216468,
20150216469,
20150216762,
20150217082,
20150219729,
20150219732,
20150220486,
20150220830,
20150223721,
20150223731,
20150223743,
20150223905,
20150226813,
20150227702,
20150227793,
20150230719,
20150230744,
20150230750,
20150231330,
20150231395,
20150231397,
20150231405,
20150231408,
20150234477,
20150235088,
20150235370,
20150235441,
20150235447,
20150238104,
20150238106,
20150238112,
20150238137,
20150238693,
20150238761,
20150238765,
20150241705,
20150241916,
20150241959,
20150242575,
20150242608,
20150242943,
20150243100,
20150243105,
20150243106,
20150245781,
20150245800,
20150246238,
20150247723,
20150247921,
20150247975,
20150247976,
20150248167,
20150248169,
20150248170,
20150248470,
20150248615,
20150248764,
20150248765,
20150248787,
20150248788,
20150248789,
20150248791,
20150248792,
20150248793,
20150250393,
20150250401,
20150250415,
20150251016,
20150253391,
20150253410,
20150254413,
20150257645,
20150257648,
20150257649,
20150257673,
20150257674,
20150257700,
20150257712,
20150262016,
20150264492,
20150265164,
20150265207,
20150265583,
20150265830,
20150265836,
20150269825,
20150272448,
20150272461,
20150272465,
20150272496,
20150272510,
20150272652,
20150273211,
20150273223,
20150282705,
20150282730,
20150282749,
20150282755,
20150282760,
20150283019,
20150283265,
20150283379,
20150283393,
20150287223,
20150289217,
20150289779,
20150289813,
20150289929,
20150290419,
20150290420,
20150290453,
20150290454,
20150293004,
20150294067,
20150294074,
20150294085,
20150294086,
20150294445,
20150296288,
20150297106,
20150297108,
20150297109,
20150297139,
20150297141,
20150297444,
20150297719,
20150297889,
20150297893,
20150301218,
20150304048,
20150304101,
20150305685,
20150305686,
20150305689,
20150305799,
20150305800,
20150305801,
20150306057,
20150306340,
20150306390,
20150306391,
20150306392,
20150309563,
20150309582,
20150310862,
20150313496,
20150313498,
20150313535,
20150313539,
20150313540,
20150313949,
20150313971,
20150315554,
20150317447,
20150317796,
20150320591,
20150321000,
20150324544,
20150324545,
20150324692,
20150325151,
20150327813,
20150327837,
20150328330,
20150328455,
20150331929,
20150332015,
20150335281,
20150335288,
20150335292,
20150335294,
20150335295,
20150335303,
20150335876,
20150335877,
20150338915,
20150339363,
20150339459,
20150342472,
20150342478,
20150342493,
20150343215,
20150343222,
20150343242,
20150351655,
20150351690,
20150351701,
20150352362,
20150352363,
20150359431,
20150359441,
20150359450,
20150359452,
20150359467,
20150359486,
20150359492,
20150360026,
20150360030,
20150360039,
20150363941,
20150366482,
20150366497,
20150366503,
20150366504,
20150366516,
20150366518,
20150366656,
20150366659,
20150369864,
20150370320,
20150370325,
20150374250,
20150374285,
20150374292,
20150374300,
20150374973,
20150374983,
20150374986,
20150374987,
20150374993,
20150375006,
20150379230,
20150379370,
20150379878,
20150380009,
20160000348,
20160000354,
20160000383,
20160001065,
20160001096,
20160001098,
20160002523,
20160004298,
20160004396,
20160004821,
20160004957,
20160005235,
20160005320,
20160007899,
20160007904,
20160007915,
20160007918,
20160007945,
20160008489,
20160008568,
20160008598,
20160008600,
20160008620,
20160008632,
20160012011,
20160012583,
20160012749,
20160015281,
20160015289,
20160015307,
20160015673,
20160016014,
20160019434,
20160019693,
20160022141,
20160022156,
20160022164,
20160022165,
20160022167,
20160022168,
20160022206,
20160022207,
20160022981,
20160023016,
20160026913,
20160027178,
20160027293,
20160027342,
20160027423,
20160029896,
20160029917,
20160029918,
20160029946,
20160029950,
20160029958,
20160029959,
20160029965,
20160029998,
20160030666,
20160030702,
20160030749,
20160030750,
20160030834,
20160031479,
20160035093,
20160038037,
20160038038,
20160038042,
20160038043,
20160038049,
20160038069,
20160038091,
20160038559,
20160038770,
20160040514,
20160044841,
20160045128,
20160045150,
20160045162,
20160045731,
20160045756,
20160048659,
20160048948,
20160048965,
20160051161,
20160051162,
20160051187,
20160051195,
20160051793,
20160051812,
20160051818,
20160055236,
20160055304,
20160055415,
20160055842,
20160058301,
20160058304,
20160058322,
20160058354,
20160058359,
20160058366,
20160058376,
20160058392,
20160058673,
20160060926,
20160062459,
20160063207,
20160063883,
20160065724,
20160065840,
20160066788,
20160066789,
20160066828,
20160066838,
20160067485,
20160067492,
20160067494,
20160067496,
20160067526,
20160070436,
20160073886,
20160073916,
20160073947,
20160073991,
20160074657,
20160074660,
20160074661,
20160077547,
20160078780,
20160081577,
20160081610,
20160081613,
20160081616,
20160081625,
20160081793,
20160082180,
20160082319,
20160084925,
20160085302,
20160086622,
20160087603,
20160089031,
20160091448,
20160095546,
20160095838,
20160096025,
20160097824,
20160100769,
20160101260,
20160102500,
20160103487,
20160103963,
20160104006,
20160106331,
20160106344,
20160106513,
20160106950,
20160106997,
20160107309,
20160107653,
20160109851,
20160109959,
20160110517,
20160110866,
20160110867,
20160112022,
20160112684,
20160113517,
20160113528,
20160113539,
20160113545,
20160113567,
20160113569,
20160113587,
20160113726,
20160114165,
20160116472,
20160116553,
20160117815,
20160117816,
20160117819,
20160119726,
20160120048,
20160120428,
20160120432,
20160120433,
20160120434,
20160120436,
20160120437,
20160120457,
20160120464,
20160120480,
20160121074,
20160121114,
20160121116,
20160125228,
20160125572,
20160128589,
20160128596,
20160128597,
20160128632,
20160128661,
20160128864,
20160129249,
20160131723,
20160132654,
20160133015,
20160135691,
20160135727,
20160135748,
20160135754,
20160136423,
20160136427,
20160136429,
20160136430,
20160136443,
20160139215,
20160140306,
20160140313,
20160140707,
20160140834,
20160140975,
20160143540,
20160143541,
20160143554,
20160143560,
20160143574,
20160143582,
20160143594,
20160144175,
20160144186,
20160147964,
20160148077,
20160148371,
20160148372,
20160148400,
20160148531,
20160150988,
20160151014,
20160151018,
20160151628,
20160152233,
20160155005,
20160157742,
20160157773,
20160157777,
20160157828,
20160158553,
20160158554,
20160162652,
20160164813,
20160165852,
20160165853,
20160166169,
20160166197,
20160166199,
20160166205,
20160166207,
20160166208,
20160166219,
20160167672,
20160168137,
20160170996,
20160170998,
20160171514,
20160174099,
20160174862,
20160174863,
20160174867,
20160174907,
20160175557,
20160175607,
20160176053,
20160178392,
20160180042,
20160180054,
20160180055,
20160183812,
20160183828,
20160183861,
20160183881,
20160184029,
20160184596,
20160184599,
20160187524,
20160191517,
20160192841,
20160192842,
20160192847,
20160192879,
20160193499,
20160196185,
20160196393,
20160196635,
20160196758,
20160198950,
20160198963,
20160198966,
20160198968,
20160198973,
20160199241,
20160199577,
20160199656,
20160199662,
20160202755,
20160203597,
20160203726,
20160204937,
20160205450,
20160205489,
20160206236,
20160206241,
20160206380,
20160206581,
20160206671,
20160206871,
20160206877,
20160206880,
20160210872,
20160213261,
20160213276,
20160213314,
20160213317,
20160213947,
20160216760,
20160217586,
20160217595,
20160219345,
20160220133,
20160220134,
20160220136,
20160220163,
20160220166,
20160220439,
20160220821,
20160220836,
20160220837,
20160220850,
20160222073,
20160223622,
20160223627,
20160223703,
20160224757,
20160224803,
20160228019,
20160228028,
20160228029,
20160228059,
20160228064,
20160228204,
20160228640,
20160228702,
20160228705,
20160231401,
20160232330,
20160232625,
20160232667,
20160232811,
20160235323,
20160235324,
20160235341,
20160235351,
20160235352,
20160235359,
20160235980,
20160235983,
20160238673,
20160239084,
20160239966,
20160239968,
20160240212,
20160240765,
20160242645,
20160242659,
20160242665,
20160242669,
20160242670,
20160242690,
20160242699,
20160243362,
20160243381,
20160245670,
20160245766,
20160245952,
20160246939,
20160247064,
20160248434,
20160248994,
20160249826,
20160249841,
20160249846,
20160249857,
20160249864,
20160250355,
20160250465,
20160250473,
20160256063,
20160256086,
20160256105,
20160256108,
20160256109,
20160256112,
20160256118,
20160256130,
20160256690,
20160256691,
20160256693,
20160257957,
20160259085,
20160259905,
20160260216,
20160261962,
20160262623,
20160262664,
20160262680,
20160262685,
20160262695,
20160262703,
20160263318,
20160263376,
20160263380,
20160263393,
20160267809,
20160270656,
20160270723,
20160274660,
20160275536,
20160278651,
20160278653,
20160278662,
20160278672,
20160278687,
20160278697,
20160278713,
20160278736,
20160278870,
20160279021,
20160279022,
20160279023,
20160279024,
20160279025,
20160279267,
20160279410,
20160279417,
20160279435,
20160282113,
20160282941,
20160284082,
20160287117,
20160287118,
20160287120,
20160287142,
20160287157,
20160287162,
20160287166,
20160287169,
20160287308,
20160287334,
20160287436,
20160287869,
20160287871,
20160287889,
20160287895,
20160296157,
20160296287,
20160296746,
20160298449,
20160299568,
20160300252,
20160300352,
20160302683,
20160302704,
20160302709,
20160302711,
20160302720,
20160302737,
20160303322,
20160303396,
20160303397,
20160303402,
20160306844,
20160306942,
20160310031,
20160310070,
20160310071,
20160313408,
20160313417,
20160313418,
20160313798,
20160317056,
20160317060,
20160317077,
20160317383,
20160317824,
20160320210,
20160321742,
20160324445,
20160324457,
20160324465,
20160324478,
20160324580,
20160324677,
20160324942,
20160325111,
20160331264,
20160331307,
20160331952,
20160331970,
20160331974,
20160331982,
20160334475,
20160334534,
20160334866,
20160338608,
20160338634,
20160338644,
20160338798,
20160338825,
20160339237,
20160339238,
20160339239,
20160339242,
20160339243,
20160339300,
20160341684,
20160342241,
20160342762,
20160345856,
20160345895,
20160345901,
20160345911,
20160346530,
20160346542,
20160351069,
20160354003,
20160354027,
20160356911,
20160357003,
20160357256,
20160360100,
20160360965,
20160360970,
20160361021,
20160361027,
20160361041,
20160361532,
20160361534,
20160361540,
20160361546,
20160363483,
20160364859,
20160364860,
20160364861,
20160366462,
20160367138,
20160367186,
20160367195,
20160367198,
20160367204,
20160367209,
20160367808,
20160367812,
20160371387,
20160371455,
20160371721,
20160374581,
20160374616,
20160374618,
20160374990,
20160375245,
20160375259,
20160378608,
20160378965,
20170000324,
20170000325,
20170000326,
20170000329,
20170000330,
20170000331,
20170000332,
20170000333,
20170000334,
20170000335,
20170000337,
20170000340,
20170000341,
20170000342,
20170000343,
20170000345,
20170000404,
20170000422,
20170000454,
20170000683,
20170001016,
20170001032,
20170006931,
20170007111,
20170007115,
20170007116,
20170007122,
20170007123,
20170007165,
20170007173,
20170007182,
20170007450,
20170007799,
20170007820,
20170007828,
20170007843,
20170010469,
20170010470,
20170013562,
20170014037,
20170014080,
20170014083,
20170014625,
20170014630,
20170017083,
20170020434,
20170020447,
20170020454,
20170020627,
20170021158,
20170021161,
20170024886,
20170027467,
20170027517,
20170027521,
20170027539,
20170027651,
20170027812,
20170028563,
20170031440,
20170031441,
20170032098,
20170032221,
20170032524,
20170032527,
20170032544,
20170034638,
20170035309,
20170035317,
20170035344,
20170035392,
20170036024,
20170039591,
20170039706,
20170041699,
20170042430,
20170042444,
20170042469,
20170042474,
20170042475,
20170042476,
20170042485,
20170042713,
20170042827,
20170043160,
20170043166,
20170043167,
20170043178,
20170045601,
20170046052,
20170046971,
20170050046,
20170052170,
20170053082,
20170053088,
20170053092,
20170053461,
20170053513,
20170053665,
20170055839,
20170055898,
20170055900,
20170055913,
20170056363,
20170056467,
20170056642,
20170056655,
20170056663,
20170060298,
20170061034,
20170061589,
20170061760,
20170065199,
20170065218,
20170065229,
20170065349,
20170065379,
20170065638,
20170065816,
20170066806,
20170067323,
20170069306,
20170071495,
20170071521,
20170071523,
20170071529,
20170071532,
20170071537,
20170071546,
20170071551,
20170071552,
20170076452,
20170079538,
20170079543,
20170079573,
20170079588,
20170079589,
20170079596,
20170080050,
20170080234,
20170080256,
20170080320,
20170084175,
20170084187,
20170085547,
20170085855,
20170086672,
20170086695,
20170086727,
20170086729,
20170086763,
20170087302,
20170087330,
20170087354,
20170087355,
20170087356,
20170087364,
20170087367,
20170090475,
20170091418,
20170091567,
20170094385,
20170095157,
20170095174,
20170095199,
20170095670,
20170095676,
20170095721,
20170099479,
20170099713,
20170100051,
20170100540,
20170100591,
20170103440,
20170105647,
20170106193,
20170107575,
20170108926,
20170112379,
20170112403,
20170112427,
20170112446,
20170112577,
20170112671,
20170112947,
20170113042,
20170113046,
20170113056,
20170113057,
20170117866,
20170119270,
20170119271,
20170119994,
20170120041,
20170120043,
20170120052,
20170120054,
20170120066,
20170127727,
20170127946,
20170128006,
20170128015,
20170128032,
20170131293,
20170132816,
20170133576,
20170133577,
20170135594,
20170135597,
20170135604,
20170135626,
20170135629,
20170135631,
20170135633,
20170135640,
20170136238,
20170136240,
20170136264,
20170136265,
20170138132,
20170140124,
20170143231,
20170143249,
20170143255,
20170143257,
20170143259,
20170143266,
20170143267,
20170143268,
20170143273,
20170143280,
20170143282,
20170143442,
20170143550,
20170143960,
20170143963,
20170143966,
20170143986,
20170146386,
20170146387,
20170146390,
20170146391,
20170146615,
20170146801,
20170147578,
20170147754,
20170148213,
20170148240,
20170148340,
20170148592,
20170149945,
20170150896,
20170150916,
20170150921,
20170150925,
20170151433,
20170151435,
20170151436,
20170154167,
20170156593,
20170156606,
20170156622,
20170156655,
20170156662,
20170156674,
20170157343,
20170157402,
20170157410,
20170160360,
20170162072,
20170164861,
20170164862,
20170164876,
20170164878,
20170164893,
20170164894,
20170164895,
20170164901,
20170165020,
20170165481,
20170165496,
20170168121,
20170168566,
20170168568,
20170169714,
20170171441,
20170172414,
20170172446,
20170172499,
20170172501,
20170172520,
20170172527,
20170173262,
20170173326,
20170173391,
20170177023,
20170178001,
20170178340,
20170180558,
20170181252,
20170181693,
20170182176,
20170182285,
20170182312,
20170185149,
20170185714,
20170185741,
20170188862,
20170188865,
20170188866,
20170188868,
20170188869,
20170188870,
20170188872,
20170188876,
20170188905,
20170188916,
20170188922,
20170188932,
20170188933,
20170188947,
20170188992,
20170189685,
20170189686,
20170189687,
20170189688,
20170189689,
20170189691,
20170189700,
20170189707,
20170190765,
20170193161,
20170193831,
20170196497,
20170196501,
20170196503,
20170196519,
20170197080,
20170197081,
20170197086,
20170198017,
20170198349,
20170199251,
20170202474,
20170202475,
20170202476,
20170202518,
20170202621,
20170202633,
20170203154,
20170205259,
20170206654,
20170206691,
20170206913,
20170209043,
20170209044,
20170209053,
20170209062,
20170209083,
20170209094,
20170209225,
20170209389,
20170209737,
20170212188,
20170213339,
20170214786,
20170216595,
20170221206,
20170224990,
20170224994,
20170231560,
20170239486,
20170239489,
D627476, Aug 29 2007 DiLorenzo Biomedical, LLC Medical patient advisory device
RE34015, Aug 07 1987 The Children's Medical Center Corporation Brain electrical activity mapping
RE38476, Mar 07 1991 JPMorgan Chase Bank, National Association Signal processing apparatus
RE38749, Nov 12 1993 LIFEWAVES INTERNATIONAL, INC Chronotherapy exercise technique
RE44097, Jul 22 2005 Psigenics Corporation Device and method for responding to influences of mind
RE44408, Dec 30 2003 CALLAHAN CELLULAR L L C RFID system and method for tracking environmental data
RE45336, May 18 2006 Arena Pharmaceuticals, Inc. Primary amines and derivatives thereof as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
RE45337, May 18 2006 Arena Pharmaceuticals, Inc. Ethers, secondary amines and derivatives thereof as modulators of the 5-HT2A serotonin receptor useful for the treatment of disorders related thereto
RE45766, Dec 30 2003 CALLAHAN CELLULAR L L C RFID system and method for tracking environmental data
RE46189, Aug 16 2010 Brainscope Company, Inc.; New York University Field deployable concussion assessment device
RE46209, Jun 16 2004 EKOS LLC Glue composition for lung volume reduction
///
Executed onAssignorAssigneeConveyanceFrameReelDoc
Dec 31 2018Neuroenhancement Lab, LLC(assignment on the face of the patent)
Dec 31 2018POLTORAK, ALEXANDER I, DR Neuroenhancement Lab, LLCASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS 0478770479 pdf
Oct 20 2022NEUROENHANCEMENT LAB LLCNEUROLIGHT INCCHANGE OF NAME SEE DOCUMENT FOR DETAILS 0684900431 pdf
Date Maintenance Fee Events
Dec 31 2018BIG: Entity status set to Undiscounted (note the period is included in the code).
Feb 12 2019SMAL: Entity status set to Small.


Date Maintenance Schedule
May 03 20254 years fee payment window open
Nov 03 20256 months grace period start (w surcharge)
May 03 2026patent expiry (for year 4)
May 03 20282 years to revive unintentionally abandoned end. (for year 4)
May 03 20298 years fee payment window open
Nov 03 20296 months grace period start (w surcharge)
May 03 2030patent expiry (for year 8)
May 03 20322 years to revive unintentionally abandoned end. (for year 8)
May 03 203312 years fee payment window open
Nov 03 20336 months grace period start (w surcharge)
May 03 2034patent expiry (for year 12)
May 03 20362 years to revive unintentionally abandoned end. (for year 12)